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-
THE DIFFUSION AND lvlETABOLISlvl OF
NORADRENALINE IN THE ARTERY I,'IALL
A THESIS SUBMITTED FOR TI{E
DEGREE OF DOCTOR OF PHILOSOPHY
RAYMOND GREG0RY M0RRIS, B.Sc.
DEPARTMENT OF CLINICAL AND EXPERIMENTAL
PHARMACOLOGY
THE UNIVERSITY OF ADELAIDE
SOUTH AUSTRALIA
JANUARY I 982
by
CHAPTER 3.
CHAPTER 4.
UPTAKE AND METABOLISM OF
IN ISOLATED ARTERY STRIPS
INTRODUCTION
METHODS
RESULTS
( I ) Rese rp'i ne
(2) Kinetics
(3) Segments
(4) Prazosin
(5) Cocaine and hydrocortisone,DI
SCUSS ION
3H. t¡oRRoRENAL INE
3H . ¡rR tt't
PAGE
43
45
45
45
48
50
50
53
53
57
58
61
61
65
7t
7T
7t
74
78
78
82
DIFFUSION AND METABOLISM OF
PERFUSTD ARTERY SEGMENTS
INTRODUCTION
METHODS
RESULTS
( 1) Metabot i te di stri bution
(2) Constriction
(3) DOPEc formation ratio
(4) Neuronal and extraneuronal uptake
i nhi bi ti on
(a ) Cocai ne
(b) hydrocortisone
(c) phenoxybenzami ne
(5) Gradient of concentration
(6) Influence of flow rate
CHAPTER 4.
( cont. )
CHAPTER 5.
CHAPTER 6.
DI SCUSS ION
( 1 ) Ori gi n of metabol i tes
(2) Di ffusion model
(3) Constriction and flow rate
(4) Uptake ínhibition
(a) cocaine
(b) hydrocorti sone
(c) phenoxybenzamine
(5) OMDA formation
'(6) Summary
DIFFUSION AND METABOLISM OF
IN PERFUSED ARTERY SEGMENTS
I NTRODUCTION
METHODS
RESULTS
DISCUSSION
METABoLTSM 0F (-)3H.DOPEG rN
ISOLATED ARTERY STRIPS
INTRODUCTION
METHODS
RESULTS
DISCUSS ION
3H. rso
PAGE
B4
84
85
90
92
92
95
95
96
9B
100
100
r02
104
108
109
113
115
CHAPTER 7.
CHAPTER 8.
DIFFUSION OF NA ACROSS THE ARTERY WALL,
STUDIED BY THE TECHNIQUE OF OIL IMMERSION
I NTRODUCTION
METHODS
(1) Perfusion system
(2) Experì mental
RESULTS
DI SCUSS ION
,UPTAKE AND METABOLISM OF CATECHOLAMINES
IN THE NORMOTENSIVE AND DOCA-SALT
HYP,ERTENSIVE RAT TATL ARTERY AND
LEFT AI'RIUM
INTRODUCTION
MITHODS
(1) Incubation studies
(2) DOCA-salt model
(3) Endogenous catecholamine assay
RESULTS
(1) Normotensive tissues
(a) Noradrenaline
(b) Isoprenal ine
(2) Hypertensi ve ti ssues
(3) Endogenous catecholamine contents
PAGE
L22
723
L23
r25
127
L29
134
136
136
t37
t37
i39
139
746
146
151
159
CHAPTER 8.
(cont.)
CHAPTER 9.
APPENDIX 1.
APPENDIX 2.
DI SCUSS I ON
(1) Origin of metaboìites in
normotensive tissues
(a) Tail artery
(b) Atrium
(2) D0CA-sal t treatment
GENERAL DISCUSSION
(1) Resume of biochemical data
, (a) Rabbit ear artery
(b) Metabolism in artery strips
and segnents
(c) Rat taiì artery
(2) PharmacologÌcaì Implications
(a) Perfused segments
(b) Role of flow rate
(c) Magnitude of the gradient
of concentration
(d) Role of extraneuronal uptake
THE DIFFUSION OF A SUBSTANCE THROUGH A
SLAB, I^,ITH INTERNAL GENERATION OF A
METABOLITE
DRUGS AND CHEMICALS
PAGE
160
160
160
L62
163
16s
165
77L
772
173
173
776
t77
t78
184
L87
r82
BI BL IOGRAPHY
To
Hel en
Rebecca and Samuel
NA
H
OH
DOMA
0I
H2
NMN
0CH3
0cH3
VMA
t T*,H-CH?
6 rø ¡
H-OHI
CH
H-C00H4,É
HNI
H-C H2
-.,+ OHr -0H
H
1
I
II
I
I
I
tÞIc J¿
OH
OH
cH-c00HÈ'-.ÐD
0-".-õ
OH cHr
COMT Pothwoy
- - -GÞ MAO pothway
I4AJOR PATHI¡¡AYS OF NORADRENÀLINE METABOLISM
IN PERIPHERAL ïISSUES AND
MOLECULAR STRUCTURES
-JOH
11
SUMMARY
(1) The major study of this thesis deals with the relatjonsh'ip between
the metabolism of NA and its surface of entry'into the artery wall. Itwas prompted by earlier evidence that the surface of entry of NA exerted
a profound influence on'its pharmaco'logica'l actions on the isolated
artery. This influence has been attributed to the locatjon of the
'nerves at the medial-adventit'ial border, and the non-uniform gradient
of concentration of NA wjthin the artery wall when the am'ine is applìed
to one surface onìy.
(2) To study the influence of the surface of entry on NA metabolism,?,"H.NA was appìied separately to the adventitía and to the intjma (referred
to as EXT and ittf 3H.NA, respectively) of the isolated perfused r^abb'it
ear artery. The associated effluxes of metabolites into the solutjons
bathing the two surfaces were measured. Experimental conditions included
reserpi ne pretreated rabbi ts to m'inimi se retention of unchanged 3H.tr¡R
in the nerves and to enhance the formation of metabolites of neuronal
origin. The relat'ive rates of formation of one of these metabolites
(dihyclroxyphenylethylene gìyco1 , DOPEG) from EXT and from INT 3H.NA ,u.".
used as an indirect measure of the relative concentratìons wh'ich NA
achieved in the region of the nerve terminals, and hence the magn'itude of
the gradient of concentration of the amine across the vessel wall. In
a numben of experiments Ca++ free bathing med'ium containing prazosjn was
used to prevent constriction of the vessel during incubation with the3H
.l',rR.
(3) The results showed that the surface of entry exerted a profound
effect on the metabolism of 3H.¡¡R, in that rxt 3H.NA lvas metaboljsed
primarily by neuronal monoamine oxidase (MAO), with DOPEG as the principaì
metabol i te, whereas lttt 3H.NA formed consi derab'ly I ess DOPEG and was
'tl1
metabol'ised primarily by extraneuronal catechol-O-methyl transferasea
(COMT) to "H.normetanephrìne (NMN). The difference between these
metabolite patterns is expìained in terms of the gradient of concentration
of INT 3tt.tlR across the wall, so that the concentration achieved in the
region of the nerves is less than that achieved by EXT 3H.ttR.
(4) The surface of entry of NA affected the efflux of its metaboljtes
in different ways, 'in that DOPEG, anC the minor neuronal metabolite
dìhydroxymandelic acid (DOMA), effluxed preferentiaììy from the adventjtial
surface irrespective of the surface of application of NA. In contrast,
NMN effluxed preferentially from the surface of entry of the NA.
The djfferencê is exp'lained in terms of the media, but not the adventitìa,
represent'ing the major barrier to the diffusjon of NA and its metabolites
within the vessel wall. This was confirmed in another study where the
efflux of methoxy-ìsoprenal'ine (Me0ISO) showed the same trend as NMN
)when "H.isoprenaline was applied to either surface of the vessel.
(5) Constriction of the vessel , in response to the 3H.i,tR, modif ied
its metabolism in several ways. As deduced from theÌr rates of eff'ìux,
the ratio of format'ion of 3H.oOpre from EXT 3H.¡tR,
compared w'ith that
from INT 3H.tlR (termed the DOPEG formation ratio) increased from a mean
value of 4.4 in relaxed arteries, to 10 in arteries which constrjcted
to INT 3tt.lttR onìy, and to 24 in vessels which constricted to INT and
¡Xt 3H.tlR. These increases imply that there is a much steeper gradient
of concentration of t¡tt 3H.NA in the constricted vessel, and are inter-
preted as evidence that, as the vessel wall thickens, there is decreased
access of INT 3H.trtR, although not EXT 3H.NA, to the region of the nerves.
In contrast to 3H.oOpEg formation, 3tt.l'tlulti formation from both INT and
rxl 3H.NA tended to decrease with 'increased constrictor response.
iv.
This finding ìs compatible with the concept of restrjcted diffusion
within the media as it constricts as well as evidence that the sites
of O-methy'lation are distributed uniform'ly with'in the media.
(6) The preceding findings accord, for the most part, with the roles
of neuronal and extraneuronal uptake and jnactivation in controlf ing
the concentration of NA in the vessel wall as deduced indirectly from
pharmacologìca1 stud'ies. In the General Discussion, attention js drawn
to some quantitative discrepancìes between the metabolic and pharmacoiogica'ì
data, principally the small effect of cocajne on the flux of EXT NA across
the vessel wal'l , compared with the effect predicted from pharmaco'logica'l
data.
(7) The results of the study also shed some further light on the possible
origins of the 0-methylated-deaminated nretabolites (OMDA). Irrespective
of the surface of entry of NA, approximately equal proportions of the
NA were metabol'ised to OMDA. This fraction was not further separated
into its constituents (tttopEe and vMA) ìn the present study. However,
it is assumed to be mainly MOPEG (3-methoxy, 4-hydroxyphenylethyìene g'lycor)
both in vielv of Íts hìgh medium to tissue ratio, and in view of earlier
evidence in non-reserpinised ear arteries where MOPEG v¡as demonstrated
to be the major constituent when analysed by th'in layer chromatography.
(B) Unl i ke 3u . nu¡¡ , the formation ot 3H
.OtrlDA was i nsensi t.ive to
corticosteroid. It is suggested that OMDA is formed by different
mechanisms in d'ifferent regions of the artery wall. The evidence is
based on the ability of a, neuronal uptake inhibitor (cocaine) to
partially inh'ibit 0MDA formation from EXt 3tl.NA, but not from Ittt 3H.tlR.
V
(9) In a separate study on artery strips, it was shown that 3H.D0PEG
is O-methylated to 3H.MOPEG by the artery by a corticosteroid-insensitive
mechanism. Accordingly the sensitivity of 3H.OMDA formation from EXT
3H.l'lR to cocaine is attributed to the ability of h'igh'ly ìipìd solublea"H.D0PEG, after its release from sympathetic nerves at the rnedial-
adventitial border, to djffuse d'irectly into the COMT-containìng
compartment. It is propclsed that this mechanism is important only'in i;he
outer region of the vessel wall. The second pathway of OMDA format'ion,
which it insensitjve to both cocaine and corticostero'id, is inhibited
by phenoxybenzamine (eAZ) and appears to operate throughout the vessel
wall.
(10) A pharmaco'log'ical study on the effect of preventing eff'lux of
INT NA and its metabolites from the advent'itia on its vasoconstrictor
activity is alsc described. To do this, the EXT aqueous bathing medium
was replaced b-v paraffin oil during a steady-state vasoconstrictor
response to INT NA. The results confirmed both the non-uniform
distribution of INT NA within the vessel walì, and pointed to the presence
of a cocaine and corticosteroid'insensitive mechanism of NA inactivation
within the vessel wa1l, in accord with the metabolic find'ings.
(11) The last study deals wjth the metabolism of NA, and'isoprenaìine
(IS0), in tail arteries of normotensive and DOCA-sa1t hypertens'ive rats.
Aìthough tangentìa'l in aim to the remajnder of the studies presented
in the thesis, it is jncluded to provide some comparative data from
another species in a s'imilar type of artery to that of the rabb'it ear.
It also provided an opportunity to study the chron'ic treatment urith a
corticosteroirl on the metabolism of 3H.run and 3l-l.IS0. This study faiìed
to reveal any consistent differences between the normotens'ive and
hypertensi ve ti ssues.
vi.
DECLARATI ON
I declare that this thesis contains no material which has been
accepted for the award of any other degree or diploma in any Unìversìty,
and to the best of my knowledge contains no materiaì previousìy pubìished
by another person, except where due reference is made in the text.
RAYMOND GREGORY MORRIS,
January, 1982.
v'ii .
PUBL ICATIONS
Some of the materiaì presented in this thesis has been published
i n the fol 'lowing books and journal s : -
in: "Vascular Neuroeffector MechaniSffis"¡ ed. J.A. Bevan et al,
Raven Press (NY). 1980, p. 148-160.
Proc. Eìghth. Intern. Congr. Pharmacol. Tokyo, 1981. abstract 1892.
Blood Vessels 18: 277. 1981.
Aust. Physiol. Pharmacol. Soc. Proc. 8: 159P. 1977.
Aust. Physiol. Pharmacol. Soc. Proc. 10: 207P. 7979.
Cl in. Exp. Pharmacol . Physiol . 6: 645 (abstract 15 ) .
Clin. Exp. Pharmacol. Physio'1. (Dec., 1981 meeting ASCEP, in press).
Clin. Exp. Pharmacol. Physioì. (Dec., 1981 meeting ASCEP, 'in press).
Proc. Fourth. Meeting on Adrenergic Mechanisms. Porto, 1981. p. 7S-9I.
vl l I .
ACKNr]hjLEDGMENTS
My sincere gratitude to my supervìsor, Professor I.s. de la Lande,
for the encouragement, i nval uabl e advi ce and constructi ve cri ti ci sm
throughout the course of this study.
I gratefully acknow'ledge the assistance of the following persons:
Mr. R.J. Irvine for basi c instruction in much of the methodology and
particular'ly for assistance in instituting the cascade column
chromatographic method in this laboratory; Mr. G.A. Crabb for assay'ing
the tìssue endogenous catecholamines (chapter B); l4rs. J.R. Jonsson
for some indirect blood pressure measurements and column chromatography;
Miss Y.K. Lungershausen for ass'istance with photography; Mrs. S. Brockhouse
for ski l f ul typi ng and to Mr . H .c . Momi s for assi stance wi th the
man uscri pt .
I gratefully acknowledge the expertise of Dr. T.N. Smjth of the
Department of Chemical Engineerìng for deriving the theoretical nrodel
of the diffusion of a substance through a slab with internal generation
of a metabolite (presented in Appendix 1).
This study t^/as supported by the National Health and Medical Research
Council of Australia.
CHAPTER 1
GENERAL INTRODUCTION
)
CHAPTER 1
GENERAL INTRODUCTION
The general theme of the study, described in the first and majgr part
of this thesis, is the influence of inactivation of noradrenaline (NA) on
its concentratjon at o-receptors on vascular smooth muscle cells. Specif-
icalìy, the study consjders, in the rabbjt ear artery, the influence of
the surface of entry of NA into the vessel wall on its subsequent djffusion
and metaboljsm. From the nletabolic changes, inferences are drawn about the
gradient of concentration of NA within the artery wall. To assist in the
interpretation of the data on NA metabo'lism, the metabolism of another
catecholam'ine,, isoprenaline (IS0) has also been studjed.
The second part of the thesis describes the accumulation and metabolisnl
of NA and of IS0 in the rat tail artery. 0rig'ina1'ly it was intended to
ascertain whether the relationships between the surface of entry of NA and
i ts metabol 'ism, as establ i shed 'i n the rabbi t ear artery, appl i ed to the
rat tail artery and then to determine whether the relationslrips rvere modifjecl
during experimental hypertension. Time djd not allow this second stucly to
be comp'leted; however, suffjc'ient data was obtained on the origins of the
metabolites of NA and IS0 in this vessel ìn normotensive and in DOCA-salt
hypertensive rats to justify its presentation in the thesis.
The following introduction descrìbes pharmacological, histochemical
and biochemical evidence dealing with the relationships between the
constrictor response to NA and its inactivation in the artery wall. The
evi dence refers mai n'ìy to the rabbi t ear artery
?
1. PHARMACOLOGY AND HISTOLOGY
It was shown in 1967 by de la Lande and Waterson (nU) and by
l^laterson and Smal e (1967) ttrat the sympatheti c nerves 'innervati ng the
central artery of the rabbjt ear, terminated'in a dense sheath at the
border of the media and the adventitia. This was later confirrned by
Burnstock et al. (1970) and by Bevan et al.G972b). De la Lande et al.
(tgøl) also showed that the sensitivity of the artery to NA was markedly
influenced by the surface of entry of the NA into the vessel wall, such
that NA applied to the adventitia was 10-20 times ìess potent in producìng
vasoconstriction than NA appì'ied to the jntima. (Note:- Throughout this
thesis, NA applied to the adventitia, i.e. the extralunrinal surface of the
vessel, will be abbreviated to EXT NA; and NA appìied to the jntima, i.e.
the intraluminal surface of the vessel, will be abbreviated to INT NA.)
The difference in sensitivity was greatly reduced by either cirronic
homolateral syrnpathetic denervation or by pretreatment with coca'ine as a
result of a marked increase Ín sensitivity of the vessel to tXT NA. The
potentiat'ion of the response to INT NA was relat'ive1y mìnor (approxìmately
1.5 fold) and was attributed to the failure of neuronal uptake to influence
the concentrat'ion of NA in the med'ia when the amine entered via the intinlal
surface. they proposed a simple model (Fig. 1"1) to explain the result.
It illustrates that when NA enters the vessel via the intima, ìt reaches
the nerve terminal region only after diffusìng through the smooth muscle
layer. llence the concentration of NA at receptors on most of the srnooth
muscle cells ín the media would not be great'ìy influenced by neuronal uptake.
In contrast, NA entering via the adventítial surface must first negotiate
the neuronal uptake barrier before diffusìng to the receptors cn the
underìying smooth muscle cells. Their model assumecl that the concentration
of NA was unìform throughout the nredia (except in the immediate environment
of the nerves where it was decreased by neuronal uptake). llowever, it was
3
soon realised that this model was oversìmplified; de la Lande et al. (1970a)
found that the loss of noradrenergìcfluorescence in the nerve terminals of
monoamine oxidase (MAO) 'inhibited ear arteries from rabbits pretreated
with reserpine could be restored by exposìng the vessel to EXT NA.
However, when the same concentration of amjne was app'l'ied to the INT
surface restoration offluorescencev¡as not detected. They suggested that
enzymic inactivation iimited the penetration of INT NA, but not EXT NA, to
the region of the nerve ternrinals. This was supported by evidence that
partial restoration of fluorescence occurred when U0521, an inhìbitor of
catechol-0-methyìtransferase (CONT), or metanephrine, an inhibitor of
uptake jnto smooth muscle cells, was present (de la Lande et al", 1974).
Hence it appeared that uptake and metabolism of the amine into the snlooth
muscle cel'ls may pìay a sign'ificant role in deternrining the concentraticn
which INT NA achìeves in the regìon of the nerve ter¡ninals. Other indirect
evidence of limjted penetratìon of INT NA to the regìon of the nerve terrninals
was provided by de la Lande and Jellett (1972) jn the course of studies
examining the effects of MAO inhibitors on the constrictor nesponse of the
rabbit ear artery to NA. They showed that nialamide sensitised the artery to
EXT NA, but not to INT NA. The mechanism of the sensitisatìon appeared to
be the same as in the guinea pig atria (Furchgott and Sanchez Garcia, 1968)
and in the cat nictítatjng membrane (Trendelenburg, I97I). It involves
uptake of NA by the sympathetic nerves. Because intraneuronal MACJ'is inhjbited
the NA accumulates in the cytop'lasm of the nerve unt'il its rate of efflux
equals its rate of uptake, i.e. net uptake is zero. Hence the failure of
nialamide to jncrease the sensitivity to INT NA indicatecl a failure of
INT NA to penetrate to the reg'ion of the nerve terminuir. De la Lande and
Jellett aìso poìnt.ed out that their results constituted pharmacoìogical
evidence for the presence of intraneuronal MAO, and that the failure of
nialamide to modify the magnitude of the response to IN'I NA indìcated that
extraneuronal MAO was of little funct'ional ìmportance in the inactivation
of NA in the rabbjt ear artery.
att 'D1- -'aa
tI¡
I
t,
ìo?
I
J\
¡ t\ 2
I¡I
4
NERVETERMINALS
LUHE N
HED IAADVENTINA
Fig. 1.1 A diagramniàtic representation of the influence of uptakeof NA by the syrnpathetic nerve terminals on the concentration
of NA in the smooth muscle of the rabbit ear artery. The arrowsindicate the diffusion of NA and their thickness indicates therelative concentration of NA in the vesseL wall.
NERVE TERHINALS(confaining MA0 )
1to1t \\t
,
I,\ a\
\ a
t
,,
ìì --2
t COM
\ I
Fiq. 1. 2 A diagramma tic representation of the influence of neuronalUnlike Fig. 1.1, this model incorporates theuptake.
the influence of restricted diffusion of NA through the media' partlyas a consequence of extraneuronal uptake and metabolism by COMT.
5
Independent evidence of a non uniform (i.e.declin'ing) gradìent of
concentration of agonìsts across the vessel wall when they entered via one
surface on'ly was provided by Kalsner (I972a) Fle showed that when an agonìst
was applied to both surfaces of the rabb'it ear artery simultaneously, the
sensitivity to the agonist was 2-3 fold greater than when jt was appìied
to one surface onìy. He suggested that this indicated that the receptors
on the smooth muscle cells were not uniformly occupìed by the agonìst at
increasing depths of the media. He suggested also that those cells nearest
to the surface of applicatjon were exposed to the greatest concentration of
amine and therefore contributed more to the constrictor response than CIjd
more distant c'ells. Since histamine and K+ behaved like NA, it lvas eviclent
that enzymic inactivation was not the only factor limiting the penetration
of INT NA to the region of the nerve terminals. An obvious factor to be
considered was the pureìy physical one, namely the decljne in concentration
within the vessel wall 'imposed by the diffusivity of the agonìst. This
factor is considered Iaterin this General Introduction (p.23). There were
thus three separate lines of evídence suggesting that the concentratjon
which INT NA ach'ieved in the region of the nerve terminals was less than
that achieved by EXT NA in the same region. For th'is reason, the model
shown ín Fì9. 1.1 has subsequently been modìfied, as shown in Fig. I.2, totake into account the possibìlity that the m'inor role of neuronal uptake
in the response to INT NA may have reflected a declining concentraticn
of INT NA between the intima and the nerve terminal region.
The pharmacoìog"ica'l ev'idence in two of the above studies (de 'la Lande
and Jellett, Ig72, and Kalsner, lgl2) was based on the assumptìon that the
sensitivity of the outer and inner smooth muscle cells of the artery media
were identical, i.e. when the concentration of NA at the receptors on a
smooth muscle cell was the same, the ce11 contracted to the same extent
6
irrespective of its posìtìon in the medja. In the case of the rabb'it ear
artery, evidence in support of this assumption is based on the observatjon
that, when neuronal uptake is blocked, the djfference in sensitivities is
snlall, amountìng only to about a 1.5 foìd greater sensitivity to INT NA.
(It should be noted that sens'it'ivity refers to comparisons of steady state
responses to sustained application of NA.) llolever, Graham and Keatinge
(1972) suggested that tl'ris assumptìon is open to question. They shor,red
that the inner smooth nluscle cells of the sheep carotíd artery responded
to a lower concentration of NA than did the outer snloo't,h muscle cells.
They suggested that the greater sensit'ivity of the inner cells was analogous
to denervation supersensit'ivity sìnce the greater distance of these ceìls
from the nerve terminals meant that they were exposed to lower concentratjons
of transmitter than were the outer cells (i.e.cells close to the nerves).
They suggested that this "supersensitivity" of the'inner cells was a useful
compensatory mechanism which ensured that they could respond to the lower
concentrations of transmjtter. The magnìtude of the difference in sensìtivìty
was 15 fold and v/as more manked for NA than for the other agon'ists testeC
(i.e. histamine, angiotens jn and serotonìn) and pers'istecl in the presenc.e
of neuronal uptake inhibjtion by desinripramíne.
Evidence which suggested that the kinetjcs of the responses of the
smooth muscle cells to NA differed'in different regions of the artery vralì
was presented by Pascual and Bevan (1979). These workers studied the
contractile responses of rabbit aort'ic strips when the entry of drugs
from one or other surface of the vessel was blocked by,a coa.ting of sjlicone
grease. They showed that when NA entered the cocaine-treated vessel v'!a the
intima, the contractjle response reached a higher steady state level and
possessed a shorter'latency and with a higher init'ial veìocìty when the
7
amine entered via the intimal surface than when it entered via the adventitial
surface. They showed that when the amine entered via both surfaces simul-
taneousìy, the response of the uncoated strip was the same as when itentered via the intimal surface only, impìyìng that the response of the
uncoated strip was determined largely by the NA which had entered via the
intima. Despite the above evidence of inhomogeneìty of the responses of
vascular smooth muscle cells to NA, the folìowìng qualifications should beGraham and
noted. Keatjnge's results were obtained on a vessel (the sheep carotid
artery) r¡lhose wall th'ickness (3.6mm) is approxìmately 36 fold greater than
that of the rabbit ear artery (0.1mm). If the increase in sensitivity
between the inner and outer surfaces was uniformiy distributed irr the wall
of the sheep carotid artery and was appìicable to other vesse'ls, then in
the case of the rabbit ear artery and the rabbit aorta (lvall thickness 0.3mm)
then the predicted dìfferences in sensitivity would be 1.4 and 2.2 fold
respectively. These are close to the sensítivjty differences of 1.5 fold
(reported by de la Lande et al., 1967) and 2 fold (reported by Pascual and
Bevan, 1979) in the rabbit ear artery and rabb'it aorta respectively.
Hence the different dimensions of the vessels under ínvestigat'ion may expìaìn
the apparently contradictory nature of the findings on the rabb'it ear artery
and other vessel s. Thi s poss'i bi I i ty 1 s further supported by obse¡vati ons
in the rat tail artery (wall thickness 0.07min). In this vessel Venning and
de la Larrde (1981) were unabje to detecb signÌficant differences in the
sensitivities to INT and to EXT NA, based on steady state responses of
cocai ne treated vessel s.
Another assunption which is central to the mociel of vascular sensitìvìty
proposed by de la Lande (Fjg. I.2) is that the enhanced sensitivity to
EXT NA produced by cocaine is primariìy due to the select'íve inh'ibìtory
action of the drug on neuronal uptake of NA. It has been proposed by
8
Kalsner and Nickerson(1969a) tnat in the rabbit aorta the action of cocaine
was mainìy extraneuronal. Their evidence was based on the assumption that
the rate of relaxation of aortic strips immersed jn oiì, after previousìy
contracting to NA, was a measure of the rate at wilich NA was removed from
the biophase of the postsynaptic a-receptors. The-y observed that cocajne
deìayed relaxation of the reserpine pretreated preparat'ion jrr which MAg
and COMT were inhibited; that is, it exerted its effect under conditions
where neurona'l uptake, neuronal vesicular storage and neur.onal and extra-
neuronal nietabol i sm were not operati ve. However, Trenclel enbumg (Ig74)
has suggested that these puzzfing findings can be expìained if part of
the delayed reiaxation observed in Kalsner and Nickerson's study was caused
by efflux of NA which had accumulated in nerve ter¡rinals prìor to cocaine
treatment; Kalsner and N'ickerson had appl ied coca jne on'ly during the
response to NA prior to immersing the strip in oìl. He verified this by
showing that pretreatment lvÍth cocaine 10 minutes before a contraction
i nduced by I'lA appreci abiy reduced, rathen than i ncreasecl, the sl ow rel axation
phase of the vessel.
l,'lith respect to the rabbit ear artery the simpìest conclusjon drawn
from the controversy about cocainels actjon is that, if an extraneuronal
action does contribute to the sensitìsing effect of the drug on the
rabbit ear arùery, the contribution is onìy a small one when NA js applied
to the EXT surface. This is based on the assumptìon that the small (1.s
fold) sensitjsation of responses to INT NA in the rabbit ear artery must
represent the maximum contribution which such an extraneuronal action makes
to NA sensitivìty. Such a contribution is small conpar.ed w'ith rhe 10-20
fold sensitisation to EXT NA produced by cocaine. llowever, the extraneuronal
component of cocaíne's action is probably even less than the estimate of
1-5 fold suggests. This is because cocaine does not sensjtise the rabbit
9
ear artery to the sympathomimetic amine, methoxam'ine, which unlike NA js
not a sr¡bstrate for neuronal uptake (Iversen,1967). It should be noted
that the conclus'ion of de la Lande et al.(1970a) was criticised by yong and
Chen (1975) on the basis that only two cornparisons were made between
rnethoxamine and NA. However, the failure of cocaine to Ínfluence the
sensitiv'ity to both INT and EXT methoxamine has been subsequent'ly confirnred
in a further eight rabbit ear arteries (de'la Lande, private commun'icat.ion).
From the above considerations there seems little doubt that the
modifíed model of vascular sensitivity (F'ig. r.z) proposed by de la Lande
is consistent with the known features of the pharmacoìog'ica1 interaction
between cocain'e and NA on the rabbit ear artery.
2. METABOLISM
Before considering the background evidence on the nletabolism of I,lA
in the blood vessel waì.l, it is impontant to address the basic inter-
related quest'ions that these studies are attempting to reso'lve; firs¡y,the specific morphological regions where the two primary enzymatic metabolisìng
systerns operate; secondly, the influence of the surface of entry of amines
on the metabolic pathway followed; and thirdìy, the physicìog'icaì'irnportance
of inactivation of biogenic amines in relation to theiì" source ('i.e., neurgnal
or circulating). Despite the fact that metabclic studies on the rabbit ear
artery generally confirm the interpretation of the roles of neuronal and
extraneuronal uptake and the metabolising enzymes, the evidence is
incomplete in one major respeðt. The pharmacological studies emphasise
that the functional rol es of neuronal and extraneuronal uptake and of
enzymat'ic inactivation depends on the surface of entry. However, this
factor has not been analysed in biochemical studies since these usually
10.
?
MOPE6VMA
COCAINE
NA,
c /srERjt0
7
Fig. l-.3 A diagrammatic representation <.¡f the inactivation pathwaysof NA in nerve terminal and effector cell. This shows NA
removed from the synaptic cleft by two processes,(a) by the cocaine-sensitive neuronal uptake process, followed by
deamination by monoamine oxídase (MAO) to form DOPEG and DOMA, and(b) by the corticosteroid-sensitive extraneuronal uptake processl
followed by O-methylation by catechol-O-methyl transferase (COmf)to forn NMN.
Two conceivable mechanisms for the formation of the O-nrethylated-deaminated metabolites (OMDA, ie, MOPEG and VMA) are shown.
Md0
NERVE
NA
OMA
ËFFECTOR CELL
NA
M OPE6
11.
employed artery segments or strips where 3H.tttR penetrated from both
surfaces . One mì ght argue, for exanrpl e, f rom tire b'iochenri cal stud'ies
(di scussed I ater) , that neuronal deam'inati on was the major metabol i c pathr,ray
ofNA inactivatìon. However, the pharmacolog'icaì studies of de la Lande and
Jellett (1972) demonstrated that the deaminating pathway did not signif-
icantly influence the response of the rabbit ear artery to NA entering via
the INT surface, and therefore could not be considered to be of physiologìca'l
importance in the inactiva.tion of circulating NA and adrenal'ine which act
only on cells near to the lumen. As a background to the experimental
section the following introduction will consider the evidence of the
relationship bätween the nrorphoìogy and the functional ìmportance of the llA
metabol'ising enzymesrmonoamine oxidase (MAO) and catechol-O-methyl
transferase (COMT), ìn the rabbit ear artery and other vasculaT t'issues.
These enzyme pathways are illustrated in Fig. 1.3.
(a) Monoamine 0xidase
The presence of MAO activity jn the rabbit ear artery was firstdemonstrated histochem'ical'ly by Koelle and Valk (1954), who associated
this activity with the medja using tyranrine and tryptamìne as substrates.
This was later confirmed by de la Lande and t¡iaterson (1968). Usìng
tyramine as a substrate, these latter workers showed that the MAO activìty
was distributed throughout the media and extended to the intima, but could
not demonstrate any MAO activity to be associated wìth the syrnpathetic
nerves at the medial-adventitial border. To date, the only h'istochemical
evidence for the presence of MAO activity in these nerves is indirect and
based on the findings of de la Lande et al. (1970, 1974). These workers
showed that in reserpinised vessels where the nronoamine fluorescence
characteristjc of nerves was absent, the application of NA to the advent'itial
12.
surface could restore the fluorescence, but only in those arterjes where
MAO activity was blocked wjth nialanride. However, in a biochenljcal study
Head et al. (1974) demonstrated a smal'l proportion of the total MAO activity
was associated wjth nerve termináls. This was based on a s'ignificant
15% reduction in tyramine oxidase activity in ear artery homogenates
following homolateral chronic sympathetic denervation of the vessel
for 14 days. The signìf icance of th'is sma'ì1 proportjon of MAO act'ivity
associated with nerves was indicated ìn a subsequent study by Head (1976).
He provided biochemical evidence that it was thjs neuronal MAO actìvity
which was of major importance'in the metabol'ism of 3ll.ttR. The evidence
was derived fr'om studjes on intact ear artery segments. When incubateda
with'H.NA (1.2uM) for 30 minutes, the major deaminated metabolite was
3,4-di hydroxypheny'l ethyl ene glycol ( D0PEG) . Treatment wi th iocai ne (29p¡t)
or by prìor chronic denervation reduced DOPEG formation by 79% and 87%
respectively, suggesting that a large proport'ion of the deamination was
associated rvith neuronal structures, desp'ite the fact that the extra-
neuronal MAO activity accounted for 85% of the total MAO activity when
tyramine t{as used as the substrate. Hence, he concluded that the extra-
neuronal MAO activity was of little quantitatìve importance in the
metabolisrn of the transmitter amine, NA. Earl'ier, de la Lande and Jellett(7972) had provìded pharmacological evidence that inhibition of extraneuronal
MAO had little influence on the rate of inactivation of NA in ear artery
segments when the concentrat'ion of amine was ìow (less than 3uM). Their
evidence lvas that the sensitising effect of nialamìde on the vasoconstrjctor
response to EXT NA was completeìy prevented by cocaine, or by prior chronic
denervation of the artery. In contrast, when the amine concentration was
greatly increased to 120uit1, de la Lande and Johnson (197?.) detected a 5 to 6
fold increase in NA released into the bathing soìution when MAO was inhibitecl.
13.
This effect could be equally demonstrated in cocajne treated, or inchronically denervated vessels, suggesting that the increased NA outflorv
was derived from extraneuronal structures. There is also pharmacologìcaì
evjdence that the extraneuronal MAO activìty may have a functional role
in the inactivation of tyramine. Th'is stems from the sensitising effects
of nialarnide on the indirect neuronalìy-medìated vasoconstrictor response
to tyramine. De la L.ande et al. (1970a) showed that the ind'irect response
occurred when tyramine was appììed to the EXT surface, but not to the INT
surface, implying that INT tyramine does not penetrate to the nerve terminals.
However, nialanlide treatment sensìtised the indirect response to IfrlT tyram'inè
much more than'to EXT tyramine. These workers suggestec.l that the inactivation
of tyram'ine by extraneuronal l4A0 activity in the media of this vessel
limited the penetration of INT tyram'ine to the reg'ion of the nerve
termi nal s .
The relative insignfficance of the extraneuronal MAO pathway 'in
deaminating NA was demonstratedbiochemicalìy by Head (nlA), who showed
that in segments of artery that were chron'ical'ìy denervated, or cocaine
treated, deamínation of either 3H.NA or 3n.ttNtl proceded at a very sìow
rate compared with arteries with neuronal inactivating systems intact.
In summary, the biochemical and pharmaco'logical stud'ies are in
agreement w'ith respect to t,he substrate specificity of neuronal and extra-
neuronal MAO activities. Thse indicated that tyramine was a substrate for
both neuronal and ext.raneuronal MAO pathways, whereas NA in low concentrations
was only a substrate for the small proport'ion of MAO located in neuronal
structures. This substrate specificity difference for tyramine and NA
has been reported in other tissues and will be considered again in a later
secti on ( page 20 ) .
14.
(b) Catechol-0-rnethyl transferase
Early investjgatìon jnto the localisation of COMT was hampered by the
I ack of a hi stochemi cal method to demonstrate i ts I ocal i sati on w'ith'i n
tissues. This early disadvantage may now have been rectified by the recent
immunohistochemical technjques of Lowe and Creveling (1978), who used an
antibody to COMT to demonstrate its presence in aortic and capiììary
endothelial cells and 'in myocardíal cells of the rat. Surprisìngly, the
smooth muscle cells of the aorta and coronary vessels did not display C0MT
activity. (Thìs apparent discrepancy is discussed further in Chapter 4.)
In the rabbit ear artery, the presence of COMT was dernonstrated biochemicalìy
by Head et al.'(Ig74), who showed that artery homogenates O-methylated
dihydroxy benzoic acid and that this O-methylatjon was prevented by
3,4-dihydroxy-2-methyì propiophenone (UOSZt¡, an inhibitor of COMT.
Tlie'location of the enzyme was shown to be extraneuronal as indicated by
the failure of prìor chron'ic homolateral sympathetjc denervation to influence
the activity of this enzyme. This was later supported by the studjes of
Head (1976) on the rnetabol ism of 3H.tlR in rabbit ear artery segments. The
evidence was that 3H.normetanephi'ine (3tt.NMN) formation in the intact vessel
was either unaffected or jncreased by cocaine treatment in concentraticns
which largeìy elimjnated the formation of the deaminated catechol metabolites
(DOpEe and DOMA), This result, together with those in artery homogenates
nrentioned above, did not completely exclude the possibility, however,
that a small proportion of the total COMT activìty may have been associated
with nerves. Evidence against this possibility was obtained by Head (1976).
He preìoaded the sympathetic nerves in the artery by incubating segments ina'H.NA (0.guFa) for 60 minutes. At the end of this incubation the vessels were
immediateìy inimerserl in 3H-free Krebs solut'ion containing phenoxybenzamine
(PBZ) in a concentration known to jnhibjt both the neuronal and extraneuronal
15.
uptake of NA. Durjng the second 30 mjnutes of washing, when the effluxa
was largeìy'H.NA which was present in the nerves, onìy 3H.¡lR and 3H.DOPEG
were detected in the efflux (i.e. no 0-methylated metabol'ites). In the
presence of ni al ami de , thi s ef f I ux compri sed only unchanged 3H. trtR. The
failure to detect 3H.l,tt,ttl or other O-methylated metabolÍtes implied that ifCOMT were present in the nerves, it p'layed no role in the metabolism of NA
both when the intraneuronal deaminatinE pathway ivas active, ancl when it was
not active. The pharmacologìcal stud'ies of Johnson, 1975 and de la Lande
et al., i97S) aìso supported the evidence of a pureìy extraneuronal activìty
of COMT. They showed that COMT inhibition by U0521 markedly enhanced the
sensitivity of'the ear artery to adrenaline. This action was independent of
the sLrrface of entry of adrenaline. This sensitisatjon by U0521 was not
affected by cocaìne treatment, but was completeìy abol'ished by inhibitjon of
extraneuronal uptake with the corticostero'id, D0CA. These results indjcated
that O-methylation normally decreases the concentration of adrenaline at itsreceptors and that this O-methyìatìon occurs only after its extraneuronal
uptake into effector cells. The question of the relative'importance of the
extraneuronal COMT pathr,tay i n i nacti va'ui ng catechol ami nes when compared wi th
the neuronal deaminating pathway is hence not entirely resolved, but the
above results suggest that the surface of entry of a substrate'into the vesseì
wall would be of prìme importance in determinjng which of the major enzymatic
pathways predom'inates. The biochemjcal evidence of Head (I976) suggested
that the COMT pathway was of minor importance as evidenced by the low rate
of NMN formation (representing only IA% of the total metabolite formation)
when compared with DOPEG formation (representing approximately 70% of the
total metabolite formation) when the intact artery segment was incubated with3H.¡tR (1.2ult¡). Hol,rever, in iris study, both surfaces r.rere equal]y exposed to
16.
the NA, whereas the pharinaco'log'ical ev'idence suggested that'inactivation by Cûi,ÍT night be ¡nore ìrnportant than by þ'lA0 when NA entered vja
the 'int'imã (de la Lande, 1975). For this reason, in the present study,
paraìlef incubations us'ing two preparations (representing proxìma1 and distal
portions of the same vessel) were carried out; one piece was doubly cannuìatec
and the 3H.substrate applied to one or other surface; the other pìece was
carefully cut longitudinally and incubated under identical conditions to
provide comparatjve metabolic data on the simultaneous entry of substrate
into both surfaces of the vessel.
A particular problem has been the origin of the nretabolites which are
both O-methylaled and deaminated (0MDA; i.e., M0PEG and VMA). The
biochemical evidence of Head (1976) suggested that OMDA was probably
extraneuronal in origin since cocaine failed to modify its formation.
However, the question of OMDA formation will be considered agaìn in thjs
introduction (p.19 ) and in chapters 4 and 6.
Isoprenaline has proved to be a valuable tool for investigatìon of
extraneuronal metaboì'ism, since it has Iittle affinÍty for neuronal uptake,
but a high affinity for extraneuronal uptake (compared with NA or adrenaljne)
(Iversen,1967). It was shown by Hertting (1964) that IS0 was a good sub-
strate for COMT but was not a substrate for F1AC. The on'ly metaboljte
observed in rat urine following IS0 adminis+.ration was 3-methoxy-ìsoprenal'ine
(MeOIS0). Head et al. (1980) descrìbed the factors whjch influence<l the
inactir,,ation of (j)3H.lSO in the rabb'it ear artery. They demonstrated that:-
( i ) the O-methyì ation pathway was saturabl e and' I imi tedl th'e accunrul ati on
of 3H.IS0 in low concentrations (Km = 2.7vî4),
(ii) the access of 3H.IS0 to the one O-methylating compartment was
sensit'ive to steroid treatment (in this case, DOCA), however,
(iii)3H.tSO ìtself accumulated in 2 separate compartnlents, other than
extracellular space,
17.
(iv) chronic denervation had a small significant inhibitory effect on
3H.lSO accumulat'ion, but failed to'influence the metaboìism,
suggesting that a minor proportion of 3H.IS0 accumulated in neuronal
structures but was not metabolised therein. Subsequent'iy, there
have been suggestions that chronic denervation may influence
extraneuronal enzyme activity (Branco et a1.,198lb).
(c) MAO and COMT, 0ther Tjssues
This section wi I I cons'ider further evi dence, primari 1y f rom studies i rr
the rabbi t thorac'i c aorta , of the morphol ogì ca'l ori gi ns of the metabol i tes
of NA. The accumulation and metabolism of (-¡3H.l,tR (0.¡ur,l) was compared
in the intact rabbit aorta,'its isolated media and its isolated adventitia
by Levin (Ig74). He showed that the metabolism of 3U.nR in the intact aorta
was charactenised by high rates of formation of 3H.D0PEG and 3H.NMN
representing 43% and 40% of the total metaboljte formatÍon respectively.
The other metaboljtes, DOMA, M0PEG and VMA were present in only small
amounts (3%, 72% and 2% respectively). The metabolite formation in the
isolated advent'itia was consistent with the localisation of the neuronal
uptake and deamjnating systenrs in this t'issue. The evicience was that the
isolated aclventitja had a high rate of 3H.OOpEe formation wh'ich represented
77% of the total metabolites formed and this was 10 fold greater than
3H.tt¡,lti formation in this tissue. In contrast, the isolated media formetl
mainly O-methylated metabolites, tH.Nl4N represented 74% of the total meta-
bolites formed and was 9 fold greater than the 3H.OOpEe formed in this
region of the t'issue. Comparing the isolated adventitia wjth the isolated
media, he showed that the former accumulated 5 fold more unchanged 3H.NA,
formed 10 fold more 3H.OOprO and 9 fold l.rr 3H.NMN than the latter tissue.
18.
Hence Levin concluded that the accumulation and deamination of 3H.NA and
)spec'ifically'H.DOPEG formation was primari'ly associated with the adventitja
anct that O-methylation of 3H.NA and specifically 3H.NMN fonnatìon was
primarily associated with the medja. The origins of the 0-nlethylated-deamjn¿t,::
metabol'ites was less clear. The overall rate of 3H.ONOR formation (i.e.,M0PEG plus VMA) was approx'imately 2 fold greater in the isolated media than
the isolated adventitia, mainìy as a result of the signifìcantìy greater
formation of 3H.NOpEe in the med'ia. The proportìon of 3H.oNoR formed was
nevertheless smalì representing only 8%, 16% and 14% of the total metaboìite
fornration in the isolated advent'itìa, isolated media and intact aorta)
respecti vely.
Subsequent'ly, Schrol d and Nedergaard (1981) i nvest'igated the
metabol'ites in the spontaneous efflux and electrically stimulated efflux
of 3H.NA from either the isolated adventitia or the intact rabbit aorta,
following preÏoadìng of the tissues wjth (-)3H.run. Their results in the
intact aorta were consistent with those of earlìer workers (e.g. Hensel'ing
et al., I978 â,b ; Su and Bevan, 1970). These workers all showed that
the r'est'ing efflux consisted main'ly of deaminated 3H.metabolìtes. Schrold
and Nedergaard showed that electrical stinru'lation increased the proportjon
of unchanged am'ine in the efflux, as wel'l as the total 3H ufflr*. The
stimulated efflux from the isolated adventitia showed the same pattern of
unchanged 3U.tlR ancl 3H.deamjnated metabolites as the intact aorta,
suggesting that these deaminated metabolites were formed independently of
the media. The neuronal origin of D0PEG was indÍcated by the marked
reduction in its formatÍon in electrica'ìly stimulated vessels treated with
cocaine. However, the source of the NltlN v¡as less clear in this study sjnce
on'ly minor amounts were formed (2-3i[ of the total 3H ettlux¡. This lorv
19.
rate of 3H.trt¡l¡l format'ion is consistent with the poor penetrat'ion of NA
into the media, compared with the adventìt'ia, reported by Török and Bevan
(19i1). Hence, it was difficult for Schrold and Nedergaard to demonstrate
a steroid sensjtl'vjty of thjs mjnor amount of O-methy'ìatìon. However,
they dìd observe a significant increase in NlvlN fornration urhen the intact aorta
was treated with cocajne, and this enhanced formation was abolished by the
additional treatment with corticosterone, suggesting that lJMttl was formed
in an extraneurottal, corticosterone-sens'itive compartment. Further, this '
result could not be demonstrated jn the'isolated advent'itia which suggested
that this cortjcosterone-sens'itive extraneuronal compartment was located
in the media. hl j th respect to OI\4DA format'ion, thei r resul ts suggested
that OMDA was fornied ìndependentìy of cocaine-sensitive ('i.e. neuronaì)
and stero'id-sensitive extraneuronal pathways. They attributed thjs to the
0-methylation and deamination of released 3H.f,¡R'in extraneuronal
adventitial cel ls where cortìcostero'id-sensitive uptake was not a pre-
requ'isite. Thjs possibiìity is compat'ible with the findings of Jacobowjtz
(1972), who showed that fìbroblast celìs, grown from guinea pig ventrÌcìe
in tissue culture, contained MAO and C0MT. These fibrobla.st cells have
also been demonstrated in the adventitia of the aorta (Branco et a1.,1981a)-
and hence could possibly represent the sites of extraneuronal nletabol'is¡ll
(i n parti cul ar, 0t'1DA format ion ) referred to by Schrol d and I'ledergaard.
The conclusions from the above studies in rabbit aorta are consistent
with DOPEG and DOMA bejng formed by a cocaine-sensitive neuronal deaminat'ing
pathway, that NMN formatìon proceded by an extraneuronal corticosteroid-
sensitive O-methyìat'ing pathrvay ìocated in the media, and that OMDA
formation proceded by an extraneuronal steroid-insensitjve pathlvay located
í n ei ther the medi a or the advent'iti a.
20.
Recently, Branco et al. (1981a) descnibed the uptake and metabolism
of 3H.iSO in the rabbit aorta. The'ir results w'ill be considered in greater
detail in the discussjon of chapter 5; but essentially they showed by
autoradiography that the smooth muscle cells were the prr'mary site of
0-methylation in that tissue, with some 0-methylatiou associated with
other structures in the adventitia.
( 4) Subtypes of MAO
The first direct evidence of two subtypes of MAO activity was provided
by Johnston (1968), who showed that in rat brain and liver, one variety of
MAO (type A) deaminated tyramìne and 5-hydroxytryptamine (5-HT) and was
very sensitive to clorgyline. The other variety (type B) deaminated tyramine,
but not s-HT, and was less sensitive to clorgyìine. Subsequent workers
confirmed the probable existence of two subtypes of MAO, each with
different specìficities for substrates and inhibitors (Goridis and Neff,
I97I; JarnotL I97I; Coquil et al., 1973; Knoll and Magyar, 1972).
Substrates for'type A' MAO included tyramine, NA and S-HT. Type A was
sensitive to c'lorgyì ine inhibition and its presence in sympathet'ic nerves
indicated by depìetion from chemically denervated blood vessels (Goridis
and Neff, I97I). Type B MAO only deanrinated tyramine, was inhibited by
deprenyl and appeared to be located extraneuronally, since its activity
was not influenced by chem'ical denervation of the rat mesenteric artery
(Goridis and Neff, 1973). Levin and w'ilson (1977) associated type A MAO
activity with the isolated adventitia of the rabbjt aorta, since low
doses of cjorgyline inhibited deamìnation of NA more than low doses of deorenyì:
in contrast, they showed in the isolated media, agaìn with NA as substrate,
that lotr doses of diprenyl inhibited the low rate of deam'ination more than
low doses of clorgyìine, suggesting that type ts MAO activity was associated
with the smooth muscle cells in this tissue. However, in the rat heart
2r.
there is ev'idence that type A MAO ìs the major extraneuronal as well as
neuronal enzyrne variety (Fowler et aì., i97B). Although the subtypes of MAg
have not been reported in the rabbit ear artery, there is indirect evidence
that the extraneuronal MAO may be of the type B variety. The histochemical
evidence of de la Lande et al. (1970b) showed that tyramine entering via the
INT surface t^/as a substrate for deamiìation by extraneuronal MAO, whereas
the pharrnacological results of de la Lande and Jellett (1972) showed that
NA entering via the INT surface was insens'itive to MAO inhibjtion by nialamjCa,
suggestíng, therefore, that the two amines had djfferent affinities for the
extraneuronal MAO, and the low sensitivity of NA would suggest the presence
of type B MAO activity.
3. COMPARTMENTALISATION
(a) MAO.
In a series of studies which examined the inactivation of 3H.NA (1.2u11)
in rabbit aort'ic strips, Henseìing et al ., 1978a,b; Henseling and
Trendelenburg, 1978; Henseling et al., 1973; Henseling et al. I976a,b and
Eckert et al., I976a,b, cons'idered the sites of metabolic inactivation bya
dividing the'H d'istribution in the tissue Ínto five compartments according
to their half-times of 3H efflux. These were generally, but not exclus'ive1y
associated with specifìc morphoìogical sites. The first two (.I and II)were extracellu'lar space; compartment III v¡as entireìy an extraneuronal
site from which 3H.tlR effluxed rapidly (half time of 3 minutes), the fourth
compartment (IV) was distributed between the extraneuronal cytoplasmic
and the neuronal axopìasmic accumulation (half-time of 11 m'inutes). The
compartment with the'largest half-time of efflux (95 minutes) was found to
be the neuronal vesicles (called compar"tment V). The origins of these
compartments were indicated, ìn part, by the actions of cocaine which
22.
did not'influence the fi'lììng of compartment III, but partìy and conpletely
inhibited the fìlling of compartment IV and V respectively during the
preceding incubation witfr 3U.Nn. Corticosteroid, on the other hand, onìy
inhjbited the filling of compartment III. From the composit'ion of the
3H.metabolites in the efflux, these workers consiclered that the metaboljsm
of 3H¡¡n effluxing from compartment V was primariìy via intraneuronal I,440,
and from compartment III was primarily via extraneuronal COMT. The long
half-time of efflux from compartment V (95 minutes) was due to the slorv
release of unchanged amìne from the neuronal vesicles into the axop'ìasm
where it was rapidìy deaminated (mainly to 3H.DOPEG). The presence of
a small propoftìon of 3U.trtNtr¡ 'in this late efflux was due to extraneuronal
O-methylation of th.3H.NA after jts release from the nerves. in a later
study (Mack and Bönìsch, 1979) the rate at which metabolites effluxed frorn
the tissue was shown to be consjstent with their relative lipid solubil'itjes
as Índicated by their partitjon coefficjents between octanol and water.
This test ranked the metabolites'in decreasÍng order of lipid soìubility;
MOPEG > DOPEG > NMN >> D0¡,14 > VMA, which compared favourably with the
observed rates of efflux from the tissues, i.e. DOPEG > MOPEG = NMN >> D0l4A >
VMA. They pointed out that th'is rate of appearance in the effluent does
not necessarily reflect the rate of formation; since thi;se metabolites rvith
a high ìipid soìubi'lity (i.e.DOPEG and MOPEG) wilì appear in the effluent
at a rate determined by the metabolism of 3H.NA, r,rhereas those with a low
ì'ipid soìubility (i.e.D0MA and VMA) will appear in the effluent at a rate
determined by the passage across the cell menrbrane. This rankjng order was
in good agreement r¡rith Levin (tgZ+) who arrjved at a ranking order of
appearance of metabolites in the bathing solution of DOPEG > MOPEG > NMN >>
VMA > DOMA in the sanre tissue.
23.
(b) cOMT
A detaiìed anaìysis of the kinetìc properties of extraneuronal
inactivation (i.e. compartment III and part of IV, described previously)
in the rat heart was described by Bönisch and Trendelenburg (I974) and
Trendelenburg( 1978) using 3H. tSO (0.95uM) as a substrate. Compartment iIIaccumulated and 0-methylated 3H.IS0; both processes were saturable and had
a high affinity for 3H.lsO (Km for 0-methyìation of LSc was 3.0upt).
Similar results have been reported in other tissues, ê.g. the cat nictitatìng
membrane (Graefe and Trendelenburg, 7974), the rat submaxiìlary gland
(Maior et a].,1978), the rabbit aorta (Henseìing,1980a) and the rabbit
ear artery (Heäd et aì., 1980). Each of these studies describe an extra-
neuronal O-methylatìng system characterised by a low Km (between 1.7 and
12ul'ù and sensit'ivity to corticosteroids. In the case of the rabbit ear
artery, the efflux of 3H.IS0 suggested it was derived from two compar.tments
(other than extracelluìar space), but'its O-methylation proceded in a
sing'le cornpartment (Kni = 2.7u1Ð. The relevance of the latter result to the
present study lies in the imp'l'ication that in the rabbit ear artery,
O-methylation of NA probably also occurs within a singìe compartment,
hence, multipie sources of this metabolite are unlikeìy. A,s'ingìe
0-methyla'bing compartment is not a universal feature.cf the extraneuronal
system, fcr exampìe, in the nictjtating membrane there'is evidence of a
second O-ntethylat'ing system of low affinity for catecholamines (Graefe and
Trendel enburg , I974) .
4. DI FFUSION
As indicated previousìy, there is pharmacologicaì evidence that the
concentration whích NA, entering the rabbjt ear antery vja the intirnal
surface, achieves in the reg'ion of the nerve terminals 'is 1ow compared with
NA entering via the advent'itial surface (de la Lande et a1.,1970b).
'1.0
24
î0
5 '10
oufer rad iuåi nner rod ius
FiS. L.4 This shows the steady-state concentration distribution ofa substance diffusing through the wall of a hollow cylinder.
Numbers on the curves are values of the outer radius (b) divided bythe inner radius (a). ns the walI thickness decreases (íe, b/.aapproaches one), then the concentration dístribution becomes morelinear. In the case of the rabbit ear artery, where b/a is usuall-yIess than 2, the distribution appnoximates to a lj-near gradient.This figure is derived frorn Cranl< (rgso),Fig. 5.1, p 63.
(Jcool-oC.=
0
Uqo\J(-q,
"ûrIo,l
25.
Subsequent pharmacol og'ica'l ev'i dence suggests that the dì f f erence ì n
concentrat'ion may be as much as l0 fold (de la Lande, 1975). Some of
the possible facbors which are responsìble for this d'ifference willbe di scussed. Accordi ng to F'ick ' s f i rst I aw of d'iff usì on, a grad'ient
of concentration must exist between the surface to which the amine is
appììed and the opposite surface. In theory,'if the blood vessel uras a
perfect cylinder, and the wall were homogeneous with respect to diffusìvìty
of NA, this gradient of concentration would be of the form shown'in Fìg. 1.4
(from crank, 1956; Fì9. 5.1, p. 63). As indicated, the gradient becomes
more linear when the difference between the inner and outer radì'i ìs
small, i.e.,the ratio of external rad'ius (b) to internal rad'ius (a)
approaches unìty, until it appr oximates to the linear gradient existing
across the wall of a plane sheet. Hence the relative dìstance of the
nerves from the two surfaces wi I I be one factor i n determì nì ng the
relative concentration achieved by NA ìn the reg'ion o'F the nerve termìnals.
These d'istances, estimated'in a group of h'istologìcaì sections of ear
arteries which were relaxed at the t'ime of fixation was approximate'ly
0.ll + 0.01 mm from theintima to the outer medja, and 0.08 + 0.01 mm from
the outer medja to the adventit'ial surface (Jellett, l97l). These
estimates are only approximate since the 'intima was convoluted and
the outer surface of the adventit'ia was ìrregular jn shape. Nevertheless,
they suggest that the location of the nerves at the mediaì-adventit'iaj
border was not the only determ'inant of the concentration of NA'in this
reg'ion. A second l"actor jnfìuencing the concentrat'ion of NA across the
artery waìl may be the regionaì d'ifferences'in diffusiv'ity of NA'in the
med'ia and adventitia. The evidence from a number of Iaboratories (reviewed
by de la Lande,l975) suggests that'in the rabb'it ear artery 80-90% of the3H.¡lR wh'ich d'iffuseC away from tile nerve termìnals appeared in the EXT
26
bathing solut'ion, i.e. d'iffused through the adventitia. This suggested
that the media represented a far greater barrier to the diffusion of amjne
than did the adventitia. This was supported by sinrilar evidence by Török
and Bevan, L97I; Allen et al., 1973; Steinsland et al. I973, and reviewed
by de 'la Lande, 1975. Török and Bevan (1971) showed that 'in the rabbit
aorta the faster diffusion through the adventitia resulted part'ia'lly from
its more "open fabric", s'ince they demonstrated a 59% inulin space in the
adventitia, compared wìth onìy 39% in the media. Hence the ma'in diffusiona'l
barrier in the artery wall was shown to be the medja. A third factor
determjning the am'ine concentrat'ion in the biophase is its removal by the
extraneuronal O-methylating pathway of the med'ia. The earl'ier evidence of
de la Lande et al. (1974), who studied the uptake of NA into nerves of MAO-
inhibited reserpinised ear arteries, included the demonstratjon that the
extraneuronal O-methylating system was able to influence the concentration
NA achieved in the region of the nerve terminals whc'n the arn'ine entered
through the intimal surface. The evidence was that IitlT NA onìy restored
fluorescence in the nerve ternrinals when either an inhib'i bor of extraneurona'l
uptake, or an inhjbitor of COMT (i.e., metanephrine or U0521, respectìvely)
was also present. This was supported by the pharmacologicaì ev'idence of
Johnson and de la Lande (1978) that jnhibit'ion of COMT or extraneuronal
uptake (by U0521 or DOCA respectively) caused a two fold increase jn
sensìtivity of the ear artery to INT NA. This suggested that the extra-
neuronal 0-methy'latìng system caused a reduction of approximateìy 50%
in the NA in the biophase and hence might account for some portion of the
apparent decline in concentratíon of NA, i.e. it ivould steepen the gr"adient.
A fourth factor which has no experimental support to date is the specific
binding of NA to receptors which presumably could also account for a
port'ion of the removal of amine from the extracellular solutìon and hence
increase the grad'ient of concentration of NA across the artery wall.
27.
An understandjng of these factors is important since the nature of
the gradient will determine the concentration of NA in the extracellular
environment of the cell, and hence'its availability to the receptors.
Further, in vjew of the evidence that NA is inactivated by different
mechanisms in the media and the adventitìa, one might expect that the grad'ient
of concentration wil I bear an intimate relationshjp to metabol ism, i.e. ,
metabolism may influence the grad'ient across the waì1, and hence the
gradient jtself determine the relative contribut'ion of the medja and the
adventitia to inactivation. Perhaps the most impo.*tant reason for seek'ing
information about this gradient is that in the physioìogìca'ì situatjon,
the concentration of NA in the vessel wall is probably aìwa.ys clistributed
non-uniformly; 'i .e. when released from the nerve termjnals the cotlcen-
tration of NA will decline as the amine diffuses frorn ihis region. When
circulating adrenaline and NA enter v'ia the intinral surface, the situation
is more cornp'ìex. The extent to whi ch the concentrati on cÍecl j nes
across the media towards the adventitia will be clependent on the extent
of associated release of NA from the nerves.
5 . SPECIFIC AIMS
The present study was undertaken in the expectation that, since3H.U0pfe was neuronal in origin (Head, 1976), then the relative rates of3H.
OOpf e formati on when 3tl . ttR was appì ì ed separately to the adventi ti a'l
or the intimal surface would indicate the relative concentration which
NA achieved in the reg'ion of the nerve terminals. By defining the
magnitude of the decrease in concentrat'ion between the intjma and
the nerve termina'ls, the results would provide a test of the model proposed
by de la Lande et al. (1970b) (Fig. I.2) to account for the differences jn
28.
sensit'iv'ity of the artery to INT and to EXT NA. The comparison of the
metabolism of INT and of EXT NA was also undertaken to define more
precisely the relative contribut'ions of medial and adventitial processes
in the inactivation of NA. In this respect the study can be compared rvith
those of Levin (1974) in the isolated med'ia and isolated adventitja of the
rabbit aorta. However, the study of metabolism when the amine is applied
to only one surface has an advantage in that it does not elimjnate ínter-
acti ons rvh'i ch may occur betureen the medi al and adventi ti al 'inact'ivati ng
systems. One exampìe which illustrates such an interaction is the mechanjsm
of fornration of the 0-methyìated-deaminated metabolites (OMDA) as discussed
in Chapter 6 and also in the SectionZ of thís introduction (pagelg).
As the study progressed it became apparent that the approach adopted
was lead'ing to new 'ins'ights 'into the factors influencing the metabol ism
of NA in the artery wall. One of these factors was vasoconstriction in
response to the appì'ied amine. Hence it became'important to compare the
diffusion and metabolisn of INT and of EXT 3H.t'tR in unconstricted (i.e.,
relaxed) anci ccnstricted vessels. Init'ia'lly Ca++ was omitted from the
Krebs solution to minimise constrict'ion; subsequently it was 'iound necessar)'
to include the d1-antagonìst prazosin into the bathing solution to ensure
that vasoconstrictìon djd not occur. These and other considerat'ions, whìch
are expìained in the indjvidual chapters, led the study to compare;
(1) the kinetics of metabolite fornration,
(2) the effects of reserpine pretreatment and of Ca++ on metabolite
formati on,
(3) the effects of inhibition of neuronal and extraneuronal uptake, and
of cr-receptor binding on the metabolite fonnation,
29.
(4) the effects of surface of entry on the metabolism of a catecholamjne
(IS0) which was inactivated so'le1y by extraneuronal 0-methyìatjon 'in
order to elucidate the influence of surface of entry of NA on the
formation and efflux of its O-methylated metabolites.
The study of the effects of vasoconstriction were an integral part of theff,
effects of Ca" and of q-receptor blockade. 0f the above studies (1) and
(2) are summarísed'in Chapter 3; (3) in Chapter 4 and (4) in Chapter 5.
The mechanism of formation of the O-methylated-deaminated metabolites
(OMDA) and in particular MOPEG formation from DOPEG are dealt with in
Chapter 6. Chapter 7 describes some pharmacoìogical st.udies where the
aim was to provide further information on the influence of the gradient of
concentration of NA on its pharmacologìcal response. Chapter 8 descrjbes
the metabolism of 3H.NA'in a dÍfferent vessel, the rat taiì artery. As
indicated earlier, it was lrcped this study wouìd include similar studies
to those in the rabbit ear artery to provide a comparison of the interact'ion
of the diffusion gradient and metabol'ism in a vessel with a thinner wa1l
(i.e.the rat tail artery) and then to extend thìs part of the study to a
pathologica'l state of vascular hypertrophy such as has been described in
vessel s fronr DOCA-sa'lt hypertensi ve rats. Unfortuna'uely, time di d not
allow completion of this study.
CHAPTER 2
GENERAL I'IETHODS
30
oa
a
a
Pre4 nc
0
37 c
M5 15-30nini ncubafe
5 secvash
57.C0 2
aci dexfracflo'c )
FiS. 2.L A diagrammatic representation of the procedure used forincubating rabbit ear artery strips. Any drug treatments
were applied for 30 minutes in the 'rpre-incrr tube as well as duringthe incubation with SH.l.abelled catecholamines (shown here as twosuccessive 15 minute incubations, but in many experiments comprisingone 50 mj-nute incubation) . This was foll-owed by a 5 second wash and acid(o.4M HCì.04,) extractÍon.
31.
CHAPTER 2.
GENERAL METHODS
1. INCUBATION STUDIES
(a) Isolated artery strìps
Ear arteries were removed from semi-lop- eared rabbits of a
strain developed at the Central Animal House, the Univers'ity of Adelaide.
unless othenvise stated the rabb'its (2,5-3.5Ks) had Lreen pretreated
with reserpine, 1.Orng.fg-l at 24 hours and again vrith 0.5mg.Kg-l at
3 hours prior to stunning and bleed'ing. The central artery of each
ear b/as isolated and a 20 to 25mm segment cut Iongibudinalìy with
iridectomy scissors taking care to minimíse traunra to the vessel .
This artery strip was then placed in a g'lass vial containing Krebs
solution at 37oc and bubbled with a mixture of 95% 0r, s% c}z (Fig. ?,1).
In nrany experi.rnents CaCl2 v,/as omitted from the Krebs solution (as
specified in the text) to minim'ise const¡iction u¡hen the vessel was
exposed to NA.
Artery strìps y¡ere blotted on moist fiìter paper, weighed and
then p'laced in Krebs solution for 30-60 minutes prÍor to adding
3H.catecholamine (or 3l'l.metabolite). The incubatiotl was continued for
a further 30 minutes in Krebs solution contaìnìng the 3H.catecholamine.
l,lhere the effects of drugs r¡/ere stud'ied, these were added 30 minutes
prior to and durìng ìncubation r¡¡ith the 3H. catecholamine. At the end
of the ìncubation the tissues were rapidìy removed, rinsed for 5 seconds
in 2.Om.l of 3H.free Krebs solutìon and pìaced in 0.4M perchloric acid
(containìng 3rnl4 EDTA and 10mM Nars0r) at 4oc and kept for assay the
fol I owi ng day. The i ncubati ng rnedi urn lvas inmedi ate'ly acì di f i ed wi ih
0.2m1 of 0.1M HCI and 0.02m1 of 0.61'l ascorbic acid ancl pìaced on ice.
Before assaying the acidified 'incubating medìurn, or the acid extract
of 3H renrajning in tire tissue for 3H.NA and 3l{.metabol'ites,0.lml of
each solution was sanrpled and the rad'ioactivity determined.
32
TENSION
OISrAL CANHULA
eszq,flc0, e5zq,s'tcq
EXTRALUHINAL ATilNbsaLurnN
ARTERY SEãHEHT
NO)(II'IAL CANNULA
PUHP
PRESSURErRA N SO UCE R
PEN
RECORDER
FiS. 2.2 The perfusion system used for incubating rabbit ear arterysegrments. Any drug treatments were applied to both
surfaces of the vesseL SO minutes before incubating with 3H.labelledcatecholamines, which were added either to the extraluminal bathingsolution, or to the intraluminal reservoir. Note that the INT perfusatewas recirculated during the 30 rninute incubations, following warmingand gassing in the reservoir.
a
INTRALUHINAL
RESERVOIROR6ANEAfH
blARIíING
c0 tL
33
(b) Perfused segments
Segrnents of ear arteries (15 to 25nrrn) f rom rabbi ts (as
described in (a) above) were cannulateci at both ends and placed in
organ baths containing Krebs solution bubbled rvith gs% 0, and 5% c}z
at 370C. The vessels were then perfused intraluminalìy with Krebs
solution, and the longìtudìna1 tension adjusted to 19. This techn'ique
is that of de la Lande et al (1966); it enables the two surfaces of
the vessel (adventitia and intjma) to ne bathed separately with Krebs
solution, Intraluminal peristaltic flow was nraintained at a constant
rate of 0.5nrl , min-l by means of a Desaga puìrlp (model 77z3gl). The
extraluminaÏ (EXT) bath volume was i. or Zml. Al'l segments were checked
for leakage (via si'de branches) of the ll.lr perfusate'into the EXT
bath'ing solut'ion by assessing r,rhether the EXT bath volume remained
constant, vessels suspected of leaking were discarded.
Vasoconstrictìon u/as nleasured by the inct"eased resistance to flolv
as indicated by an increase in perfusion pressure. The latter lvas
nleasured vi a a statham pressure transducer (nrode'l P23AC) ì i neated
betv¡een the punrp and the vessel, ôrìd recorded on a Rikidenki double-
channel pen recorder (model 824). As shown 'in Fìg, 2.2, a small
reservoir collected the effluent from the top cannula of the artery
so that the INT perfusate was again warrned, gassed and recirculated
through the artery durìng incubations. After 30-60 minutes perfusion,3'l lub.l led catecholamine \^/as added either (a) to the intraluminal
perfus'ing solution only (referred to as INT), (b) to the extralun'inaj
bathing solutjon only (referred to as EXT), or (c) to both the INT
and EXT solutìons simultaneousìy. Incubat.ion u/as for a 30 minute perìod
unless speci'fìed othervrise. As in the case of artery strìps, drugs vrere
34
added (to Uotn solutions s'imultaneousìy) 30 rninutes prior to comnencing
incubaiion with the labelled amine and lvere present throughoirt the
incubation period. After recording the volumes of the INT and EXT
bathing solutions, these solutions were acidìfied vrith 0.2m1 of 0.il,l HCI
and 0.02m1 of 0.6i4 ascorbic acid. lhe 3H content of 0.lm1 was measureci
and the remainder stored on ice untjl assayed for unchanged 3H. catechola¡l'ine.)
and the "l-i.metabol jte(s).
Notes:- (a) The volumes of the INT and EXT bathing solutìons were kept
small (1.0 to 2.0m1) to enable the small amounts of 3H
material which diffused across the vessel wall to be
ana'lyseci. For this reason, narrow bore tubing was used in
the perfusion lines (sjlastic pump tubing, 1.Ornm i.d. and
2,Omtn o.d. and polythene delivery tub'ing and cannu1ae,0.5mm
i.d. and 1.Omm o.d.).
(b) To enable diffusion coefficients to be measured, the ìength
of the segment and its diatneter lvere rout'inely measured
with a Zeiss binocular dissectjng rnicroscope. l,Jhen
measuri ng di ameter, â stai nl ess steel wi re of knou.ln
diameter (placed beside the vessel in the organ bath) r^ras
used for reference. When measuring 'length, a graduated
poìythene rule placed besìde the vessel was used for
reference. At the end of the experiment, the segnrent
between the cannulae ties \,/as blotted on moist filterpaper atld v¡eighed. The diffusion equat'ion ì s shown on page 42a
(c) In nlost experìrnents more than one incubation t/as carried
out on each segment. Follolving the first'incubation u¡ith3H.catecholamìne the int'imal surface was continuous'ly
perfused, and the adventitial surface washed B-10 times,
35
Table 2.1
Abbreviations
NA
DOPEG
MOPEG
DOMA
VMA
NMN
OMDA
rso
MeOISO
3H.NA
noradrenaline
3 ; z.-dihydroxyphenylethylene glycol
S-methoxy,4-hydroxyphenylethylene qlycol (ie,the methoxyderivative of DOPEG)
3, 4-dihydroxymandelic acid
vanilJ-yI mandeLic acid, or 3-methoxy,4-hydroxy mandelic acid(ie, the methoxy derivative of DOMA)
normetanephrine, (ie, the methoxy derivative of NA)
O-methylated-deaminated metabolites (ie, MOPEG + VMA )
isoprenaline
3-methoxy isoprenaline
Tritiated noradrenaline
Eff tuent41203
Sornple lpH$alWosh 4'0ml NoAce4ote 03M
E
Jr.t+¡ lzË1 zmry
---DOWEX S0Wxtr1'5 r !'! s¡¡H+ furm.pH=2
4tTl OSH
üwAs
ct*jc00H
rE 2nlo2ì,, l{l
Effluent+ 1 ml h'-0
t¿I,v
(11 0þ4pa
MoPE6 'i,r'öf|f,i.
ctLo 0H
HðþiH-coon
E[uate2'0ml 6l,l Htl:Eî0t1 + 2ml F!0
I
Eluate2'0nl 6H HCI:Et0H
uentEffr
f3I DOPEGJ
( 1:1 I
(41 F¡A (sl DoMAi{0. 0H Fto oH
ncr@xcr¡q roþtn-cooH+
VMA
Fic¡. 2.3 A flow diagram of the cascade column chromatographic assay for separating NAand its metabolites. The sample, either 1.OmI of acidified Krebs solution
(incubating medium) or 1.0m1 perchloric acid (tissue extract), brere added +,o 0.1mI EDTA(o.st'l), o.1ml Na2Sog (l-.oM), 0.o1m1 aseorbic acid (0.6M), O.O1m1 carrier sofution (each0.6t4) and 1.0m1- (medium) or 1.5m1 (tissue) of TRIS buffer (1M, pH=8.4), before loadingthe aLumina column. Note that MOPEG and VMA both appear in fraction (1). (¡)
Or
37.
with 3H-free Krebs solution at 37oC over at least a 60
minute period. When required, drugs v.rere added to the If,iT
. and EXT solutions 30 minures prior to the start of the
second incubat'ion.
(d) In most of the studies with perfused segments, artery strìps
from the same ear were incubated under otherwise identical
condjtions to provìde information on the metabolism of the
H.catecholamine when applied to both surfaces simultaneousl'.,.
2. ASSAY OF 3H.
NA AND 3H.I4TTRgoLITES
To facÍlitate presentat'ion, the abbreviat'ions used for metabolites
are represented in Tabl e 2.7. The assay for separating unchanged 3H.i'tA
and the 3H.metabolites t{as essentiaìly the sanre as that of Graefe et al
(1973). The prìncipal of this cascade column chromatographìc rnethod,
as shown in Fig. 2.3 involves separation of the catechols from the
phenolic metabolites b,v adsorption onto alumina at pH = 8.4 and
separation into aci'ds, bases and neütral compounds by neans of
adsorption onto DOWEX 50. When tissue extracts were analysed by this
method, an additional 0.5m1 of 1l'1 TRIS buffer (pH = 8.4) was a.dded to
the nrixture before loading the alumina column. At the compìetion of
the separation procedure, l.Oml of each fraction was sampled for its3H content.
The efficiency of separation and recovery of l',lA and metabol'ites
!úas rneasured by subjecting unìabelled llA and each of the nletabolites
to the above chromatographic procedure. The NA and various metabolites
in the fractions were then assayed by their native fluorescence.
The results are shown in Table 2.2.
38.
Table 2.2
The recovery of unlabelled NA and metabolites and their crossover inioother fractions using the cascade column chromatogrphic method (FiS. 2.3)
Fraction MOPEG VT4A NMN DOPEG NA DOMA
Table 2.3
The recovery of unl-abelled ISO and the metabolite and their crossoverinto other fractions using the cascade coLumn chromatographicmethod (fig. 2.4). The appearance in frac'bion 1 was not determined.
Fraction MeOISO ISO
1
u
3
n
L
2
3
4
5
4ml l¡Iash
o
o
o
0
0.3 to.0
0. 1_ t0. o
o . osto. o
77 .O L4.O
2.5 10.1
0 .4 to.0
0
o
0
2
9s.8
56 .3
1.8 4't".4
0 0
o
0
o 3
0 9
3
96 .8 92.3
2.O o.7 100
L,2
l_ .1 o
1
2
0
o
n 1 1 1 1 7 1
10o t0
? ?
0
o
gL Jl-
2 2
E ff luent 41203
Sompte {pH=8'41Wosh 4'0mt NoAcetqte 03M
E luate
2mt0.2M HCt
(1),.OM
DA" (21 MeO!S0
--DOVíEX 50hrx4
--' 1.5 xo.Scm
H' form. pH=2
El uate2'0nl 6H HCI : Et0H
ü ( t:1)
cHjo_- qH çH(cHjlzHù(Q)c H-cHãNH
(31 ts0
CH¡0. 0H CH(CH3I2
niÞtn-cn2Ñn
E fflUE nt+1mt l'lr0
¿
?
Fiq. 2.4 A fLow di agram of the cascade column chromatographic assay for separatingISO and its metabolite, MeOISO. Samples were prepared as described in Fig.2.3,
before being loaded onto the al,umina coLtmn. Therrmetabolite(s)" appearing in the OMDAfraction were not identified as they could not be demonstrated using TLC.
q)ro
40
The assay was adapted to separate unchanged 3H.ISO and its
metabol'ite as shown'in Fì9. ?.4. The recovery of unlabelled IS0 and
Me0IS0 v/as measured by assaying the fractions for their native
fluorescence. The results are shov¡n in Table 2.3. This shows that
recovery of IS0 and MeOISO was h'igh, and that no crossover of IS0
into fractìon 2, or MeOlSO into fraction 3, lvas detected. The
crossover of either cornpound 'into fract'ion 1 '¡las not measurecl.
3. SCINTILLATION SPECTROI'IETRY
The radioactivìty of sampìes \^/as determined by 'liquid scintillatíon
spectrometry, us i ng ei ther a Packard Sci nci I I at'ion Spectrometer (mode'ì
3310) or a Becknran Scintillation Spectrometer (nrodel LS 7500). The
scintillation cocktail was prepared in this laboratory and contained
toluene and triton-X 100 (2 to I ratio) and the spectrof'luors PPO
(2,5-di phenyl oxazol e ) and dimethyì -P0P0P (1, 4-b,i s (2 (-4-methyì -5-
phenyloxazolyì ) )benzene) (5.5 g.l-1 and 0.17 g.l-1 respectively). In
e'ither spectrometer, quenching was determined by reference of the
ratio of counts in 2 appropriate tritium windou¡s to a quench curve
constructed for each counter using a commercia'l'ly prepared set of
quenched standards. Hence counts per minute (CPM) vrere converted to
d'isintegratìons per minute (DPt'1) and this latter figure used in all
calculations. In the former spectrometer, samples were counted for
10 minutes, or until 900,000 counts had accumulated (whichever occurred
fjrst); and in the latter spectrometer counting proceded until a CPÍ'1
accuracy o¡ +2% was achieved, or for 10 nrinutes (vlhichever occurred
first).Quenching (ranging from 50 to B0%) was determined for every sample
counted in ejther spectrometer by reference to a quench curve constructed
using a commercial set of quenched tritium standards.
41.
4. RADI()CHEMICALS
a(a) (-)"H.(7-C) NA (Radiochemical Centre, Amersham, Batch 54), specìfic
' activity 15 Ci. mmol-l, uru, used in earìy experiments. When its
supply was discontinued, New EnEìand iluclear (Ntt,l) (-)3H.NA rvas
used. Hovlever, it was ascertained that several batches used
(NEN 1271-115, 1293-077 and 7277-039) urere part'ty labelled on the
8-C position (Starke et al,19B0; confirmed in personal communjcaticn
. with NEN). Data using these suspect batches was rejected. As llEli
would not then guarantee that.7-C labelled material was not also
lab.elled on the B-C atom, r'ing (2,5,6-C) labelled (-)3U.run
(Batch number 7277-744, specific activìty 46.5 (Ci.mnlol-l¡ uuu,
subsequently used in all experiments.
Note:- The reason for rejecti'ng the partly B-C labelled material
wôs, as shown by Starke et al (L980), (a) that 3H released by MAO
deami'natíng an B-C labelled NA molecule v¡ould appear as 3H-water
and contaminate the 0MDA fract'ion, and (b) the evidence that the
8-C labelled molecule is less active'ly metabolised by lt1A0.
Stock solutions of (-)3U.NA v¡ere a 9:1 mixture 0.ZM acetic
acid and ethanol. In the case of the 7-C (--)3H.NA, an approprìate
volume was freeze-dried and reconstituted in gassed ascorbìc
Krebs solution at 37oC immediately prior to use. The 2,5,6-C
(-)3H.1'lA, because of its higher specific activ'ity, was diluted
direct'ly with unlabel led (-)NA dissolved in normal saline
containìng 0.6mM ascorbic acid and added to gassed ascorbic Krebs
solution at 37oC (diìutìon factor approximatel-v I to 500). The
final specific act'iv'ity of the (-)3U.NA jn the incubating medium
was of the order of 4 Ci.mmol-l. The purity of the 3H.NA u¡as
routineìy determineci by 'its recovery 'in the i'lA fraction (fract'ion 4)
42
from column chroinatography. The puri ty in experiments wìth?"
7-C (-)"H.NA. was greater than B0%. In the case of 2,5,6-C (-)"H.NA,
the purity was greater than 95%. In sonre of the earlier experirnents
using the 7-C (-)3H.NA, the purity of the stock label was less
than 80%. In these cases, the stock was first purified by
adsorption onto aìumìna, as described by Head et al (1978).I(b) (+)"H.ISOPRENALINE (Radiochemicaj Centre, Amersham, batch numbers
t), rc and 18) was used. The appropriate volumes were f reeze-
dried, or vortex-evaporated to dryness, and reconstituted in gassed
Krebs solution at 37oC containing ascorbic acid (0.6mla) together
rvith urilabel led (1)lSO in the appropriate concentration. Experimerrts
. where the final concentration of IS0 was 0,1BuM, ô 1:1 dilution
of I abel led to unl abel:led IS0 was used; wlrereas i n experiments
using 0,8u1',l, â 1:9 ratio was used, Again, radr'oactive purity
lvas determined by the recovery of 3H in the iSO fraction of the
col umn chromatograph'ic assey and u,ras found i n al'l experìments
to be greater ihan 90%.
)(c) (-)'H.D0PEG, In one series of experiments the nretabolism of
(-)3H.D0PEG was examined. Since 3H.uOpee is not commercialìy
available, ìt was pnepared by tlre author. The method of prepara+"jon
and purity ìs described in detail in Chapter 6.
5
42a.
CALCULATION OF DIFFUSION COEFFICIENT
The internal radius, and hence the wall th'ickness of the artery
segment, is estimated from the fol low'ing formu'la:
o.- (u hl ,- --rllTt
where a = internal rad'ius (cm), b = external radius (cm),
w = weight (gm), and I = length (cm).
It is assumed that the specifìc grav'ity of the artery ìs .l.0.
The dìffusion coefficient is then estimated from the formula for
the diffusion of a substance across the wall of a cy'l'inder
(Crank, 1956).
D-Q, ln !
Îf ì- 2
where D =
+-L-
l\_t/l - -
^_v2-
Qt=
diffusion coefficìent (.*2.r..-l ),time (sec),
concentration of substance maintained at one surface,
concentration of substance at the opposìte surface,
flux of Substance across the wall, 'i.e., the quantity
appearing in the solution bathing the opposìte surface,
in tìme (t).
CHAPTER 3
UPTAKE AND IqETABOLISI'1 OF
3H.ttoRRuRENALiNE IN ISoLATrD
ARTERY STRIPS
43
CHAPTER 3.
uprAr,.t AND METABoL I sM or 3H. NoRADRENAL I NE
IN ISOLATED ARTERY STRIPS
INTRODUCT I ON
Although the major stud'ies 'in th'is thesis concern the metabol'ism
of NA in perfused segments of rabbit ear arterìes, the metabolism of)"H. NA 'in non-perf uied artery stri p preparat'ions wi I I be described
first as these results are essent'ial to the 'interpretation of much
of the data on the perfused segments. In the studies ìn th'is chapter,
isolated artery strips were'incubated w'ith 3tl.NA in a fixed volume
of Krebs solution (l or 2ml). Unden these cond'itions it ìs assumed
that the amjne enteretl both surfaces of the vessel simultaneousìy.
This is the usual method of studying catecholam'ine metabolism in
isolated tissues and was used'in the present study primariìy to provide
kinetìc data whìch would have proved difficult and time consum'ing to
derive from perfused segments. The kinet'ic data emphasises the
relationship between the substrate (3H.ltR) concentrat'ion and 3H.OOpue
formation. Other data presented 'in this chapter refer to the effects,
on NA metabolìsm in artery strips, of the various treatments used in
the studies on perfused segments. These treatments compared,
(a) the use of arteries from reserpine pre-treated rabbits (to m'inimjse
retention of unchanged amine in the tissue), (b) the use of ca++-free
medium (to.minimise constriction), (c) the use of prazos'in (to
abolish the constrictor response to NA), (d) the effect of cutting
the segment to form a strip, and (e) the use of cocaine and hydro-
cortisone to min'imìse neuronal and extraneuronal uptake, respect'iveìy,
of 3H . ttA.
Tal¡l-e 3.IThe accumulation and metabolism of (-)SH.¡¡R (0.18 pM) in rabbit ear artery stripsValues shown are means t SEM togetl'rer with their percentage distributions.
* Data for reserpine plus prazosin indicates efflux into the bathing medium. only.
Pretreatment Medium PreparationTissue
NAnTota1 Metabol-ism nmol. g
DOMA DOPEG NMN
-1 -L.3OminOMDA
0 .51_+o.01(r4%)
o.19lo.o4(Lr%)
o.45lo.o7(r2%)
0.39+o.09
(e%)
0.55+0.07(ß%)
o.5210.09(r4%)
0.05+0 .01(L%)
o.02t0 . o:t-
(1s)
0 .90+^ 1'7
(2r%)
o.57t0.10(L/.%)
o.37to. 08
(8%)
o.43t0 .05(7r%)
2 .08+r'ì o,)
(/,8%)
r.84lo.17(47%)
o.46+0.11(rr%)
o.72t0 .08( 182" )
o.71-+0.06
O./*910.04
2.07+o.r2
o.46+0.05
2.85+o.24(66%)
a ac.
lo.22(60%)
0. s5to.t7(ß%)
o.3910.14(Lo%)
4
4
6
1
2t
Segment
Strip
Strip
Strip
Strip
Ca++
Ca++
ca++free
Ca++
Ca++
Untreated
Reserpine
Reserpineplus
Prazosin
ÞÞ
45.
METHODS
Rabbit ear artery strips or segments were ìncubated with (-)3H.nn
as described in the General Methods (Chapter 2). The princìple of
the method was that freshly excìsed centraì ear arteries were incub-
ated for 30 m'inutes with 3H.NA ìn Krebs solutìon at 37oC and bubblecl
w'rth 95% 0r, 5% C}Z. Both segnients, and segments slit long'itudinalìy
to form strips were used. Treatments 'included reserpìne pretreatment
of rabbìts, as described in General Methods, and the presence or
absence of ca++ in the bathing medium. Drugs were present 30 mìnutes
prior to, and durìng, incubation with the 3H.t¡R. The amount of
unchanged 3H.t'lR and 3H.metabolites present'in the incubating meciium
or t'irrr. u*a.act were assayed by cascade column chnomatography
(described 'in the General Methods).
In the k'inetic stud'ies where two l5 minute 'incubations were
carried out, the procedures were 'ident'ical to the above except that
the tissue was transferred to a second tube, conta'inìng the same
incubating med'ium as the first, after l5 m'inutes (Fìg. 2.1).
Many of the experiments on strips were carried out at the same
time as those on perfused segments, the strip be'ing removed from a
more d'istal part of the ear. These experiments included those
involving drug treatments (other than the effect of reserpine pre-
treatment ) .
RESULTS
( I ) Reserpi ne: -
As shor¡ln 'in Table 3.1, the effect of reserpine pretreatment, rrrith
or without Ca++ in the bathing soìution, was to markedly reduce (by 75%)
the retention of unchanged 3H.ruR and markedìy ìncrease the formation
of the deami nated ntetabol 'ites, 3H. OOpre and 3H. DOMA (by 3 .5 f ol cl and
46
Table 3.2
Effl-ux of metabolites from reserpinised rabbit ear artery strips incubatedwith (-)3U,Ua (O.l-8 uM) in two successive 15 minute incubations, comparedwith one 5O minute incubation.Val-ues shown are means + Sflt.
Incubationtime (mins) n
Metabolite EffLux
DOMA DOPEG
nmor. g-1
NMN OMDA
L5-30
0-l_5 LL
t_ t-
o.22 lO.O2
0.29 tO.03
o.21 lO.O4
0.59 tO.05
0 . i_9 t0.03 0 .86 10.08
o.23 !O.03 1.O3 t0.L0
o -30 6 o.59 10.07 1.71 10.15 O.39 tO.04 0.48 tO.O8
TabIe MEDIUM TO TISSUE RATIOS
The relative amounts of SH.metabolites effluxing into the incubating medium, to that retained by the tissue, atthree substrate concentrations for Ca++ free media, and one concentration for Ca++ media, for rabbit ear arterystrips incubated with (-)3H.Ne.
3.3
Treatment3n.l¡e( uu) n
TissueNA
( nmol . s-1 )
Medium,/Tissue RatiosDOMA DOPEG NMN OMDA
è
2
6
5
19
l_0
11
I
2
18
L1
l_6
20
3
5
5
1
0 .01_ +0.00
0.06 +0.01
c.59 Ì0. 14
0.s5 t0.L7
4
1
6
6
0.18
o.o2
0. 05
0.18
ca++free
Ca++
4B
2.O
)ICott -free Krebs
medium ln=4-61
't.0
d -á:
T
/ --É- --'E
0 o1t3x.ruel nmol.rnl'l
o2 0.1 02I 3x.Hn I n mol. mt:1.
Fig. 5.1 The relationship between 3H.metabolite efflr.¡x (nmol.g-1.gOmin-l)and the concentration of 5H.Nn (uM) in reserpinised rabbit
ear artery strips incubated in Ca++ free and normal Ca++ Krebs solution.Circles indicate DOPEG, t"iangles indicate DOMA, squares indicate OMDA
and diamonds indicate NMI'I . This shows that DOPEG efflt¡x predominates,that efflt¡x of each of the netabolites approximates to a straight-Iineover the concentration range used and that the omission of Ca++ fromthe bathing medium had litt1e effect on metabolite efffux.
Co++ Krebs
med¡um (n=4s)
Tc.EctalT
ctloEc
g/
gt
ac.Eo(Yl
TIoEc
1
000
49
36 fold, respectively). These changes are consistent with impaired
vesi cul ar storage, and j ncreased avai I abì I'ity, of 3H. ¡tR to the 'inti.aneuronal
MAO pathway, foì ìowing reserpìne pretreatment.
(2) Ki neti cs : -
The kinetics of 3H.NA metaboljsm wìth respect to substnate
concentnation and time is presented in Fì9. 3.1 and Table 3.2. The
results in F'ig. 3.1 shows that when reserpin'ised artery strips were
incubated wjth graded concentrations of 3H,tlR for 30 m'inutes in either
Car* or Ca++ f ree med'ia , tr. D0PEG uras the princi paì metabol i te. The
relat'ive propot"tions of the tota.l nretabolites formed at 0.18u1,1 3H.trtR(Cåtfreei
comprise¿ 3ú.DopEc (sz%), tr.DoMA (zo%), 3H.ottoR (20%) and 3H.NÞill (12%).
The proportions of each of the metabolites retained in the tissue was
small compared with those whjch effluxed into the bath'ing medium during
the 30 minute incubation period. In Table 3.3, this distribution 'is
presented in terms of the ratio of the amount of r¡etabolite in the
incubat'ing nredìum to that retaìned by the tissue at each of the
substrate concentrations in Ca++ free media, and at 0"lB¡M 3H.NA in Ca**
media. In the case of the Ca++ free nred'ia incubateci with 0.lBpM 3H.NA,
the proportions retained 'in the tissue ,,... 3H.DOpEG (6%), 3H.trtNtt (g%),2?')"H.0MDA (22%) and 'H.DOMA (I7%). Unchanged 'H.NA repr-esented 4l% of
the total 3H retained in the tissue. 0f the 3H.l'lA removed fronr the
bathing medium, 10% was retained in the tissue and 90% was metabolised.
The results in Fig. 3.1 also shows that within the range of concentrations
of 3H.NA examined (0.018 to 0.18uM), the amounts of.the metabolites
which effluxed into the bathing medìum were directly proportìonal tc
the substrate concentration'in both Ca++ an,l Ca++ free med'ia. The rate
of format'ion of the metabolites was unaffectecl by the omissìon of Ca++ ,
from the bathing solution. l-here vJas a tendancy for the Ca++ free
tissues to retain less unchanged 3H.l,tR, but thjs difference was not
signìficant at the 5% 1eve1.
50.
The tìme coirnse of efflux was examined by comparing the amount of
the metabol jtes which effluxed into the bathìng mediurn during two
successive 15 minute incubations witn 3H.t'tR. As shown in Tabl e 3.2
the efflux of each of the metabolites increased in the second 15 minute
peri od. llolvever, wi th the exceptì on of 3H . OltOR, thi s 'i ncrease was
suffic'iently small (20-30%) to suggest that there was little error
involved ìn usjng the total efflux during the 30 minutes as a measure
of their respect'ive rates of fornrat'ion. In the case of 3H.ONOR a
sÍgn'ificant 60% increase in the second 15 minutes was observed. The
formation of this fraction is considered in greaten deta'iì in Chapter 6.
(3) Segments : -
The effect o the metabol'ism of 3H.NA (0.18p[1) of cutt'ing an
artery segment ìongitudinal'ly to form a strip Ís shor,vn in Table 3.1.
There was a non-significant tendency for the strip to f'oritì more 3l-i.NMN,
consistent rvìth the probabìlity that the jntimal surface was more
accessible to the substrate in the artery strip than in the segment
The artery strì'p also tendedto retaìn less unchanged 3H.ttR; this may
have reflected the trauma or injury to the nerves in preparing the
artery stri p.
(4) Prazosi n: -
The effect of prazosìn [0.ZrM) on the metabolism of 3H,NA in
artery strips is shown in Table 3.4. Although only data on the efflur
of metaboljtes ìnto the incubating nredi'um is shown, the results suggest
that the prazosin treatment was without a significant effect on meta-
bollte forntation in isolated strìps.
5t.
The efflux of metabolites into the incubatiÐg medium of reserpinisedrabbit ear artery strips incubated with (-)JH.NA (O.fA UU) in Ca++ fréemedium.Values shown are means tSEM.* indicates significance (p<O.05); unpaired t-test.
Table 3.4
Treatment(n)
Metabolite Efflux nmol.g-1.somin-lDOMA DOPEG NMN OMDÀ
o.1at 0.05
o.97lo.21
o.06t o.07
2.32+ 0.20
2.O7lo.t2
o.19r0.04
o.7L10.06
0.78 *t0.07
o.55 *+o.09
O.I2 *r0.02
t_.53lO./*9
o.77to.t l_
o.50lo.2L
Untreated(n=9 )
Hydrocortisone(n=6)
Prazosin(n=21_ )
Cocaine(n=7 )
I
i
I
I
i
I
I
;II
I
I
I
;
I
52
3 n uNTREATEo (¡:ã I
ffi a*rNE (291ì4 ¡ ¡¡=71
HYOROCORTI glNE I ¿1 3pet I
r p<o.os ln=61
T.sEc,olT
ctl-:oËc
I I
rla
0DOMA DOPEG NMN OM DA
Ficf . 3.2 The efflux of 3H.metabolites in nmof.g-1.50min-1 fromrabbit ear artery strips incubated with (-)3H.i.trR (o'fA yl'I)
in Ca++ free media with prazosin (O.Z UtvI). The effects of cocaine(Zg pt'l) and of hydrocortiscne (¿fS UM) are also shown. These arterystrips represent the distal portion of the sarne vesseLs used instudies on perfused seqments presented in Chapter 4'* indicates significance (p<0.05); unpaired t-test.
T
53
(5) Cocaine and hydrocortisone:-
The effect of cocaine (29uM), in the prazosin treated artery strìp,
on the metabolism of 3H.ruR (0.l8ultD is shown in Table 3.4 and also jn
Fig. 3.2. It shows that the efflux of the deaminated metabolites,3H.OOpfg and 3H.DOMA, was strongly jnhjbited by 94% and 83% respectively
in the presence of cocaine. The efflux of 3H.t,iNtl was signìficantly
increased by 1.6 fold. The effect of cocaine on 3H.OtlOR èfflux vras
to reduce it by 54%.
The effect of hydrocortisone (413u14), in the prazosin treated
preparation, on the metabol'ism of 3H.NA (0.1BuM), js also shou,rn in
Tabìe r.+ aía rlg. 3.2. The efflux of 3H.t'tt¡t'l jnto the bathing mediunr
r^,as reduced by BB%. The tendancy to also reduce 3U.OOpEC efflux was
not significant at the 5% level.
DISCUSSI ON
The patbern of metabolites of 3H.ttR'in untreated artery strìps
incubated in Ca++ Krebs jndicated that the major proportion (60%) of
the ami ne removed f rorn the i ncubating med'i unr was accunru I ated u nchangeci
in the tissue. In accord with earlìer findings (Head et al, L975;
de la Lande et al , Ig78; Head, 1976), DOPEG vras the prìnc'ipaì
metabolite. In contrast, the reserpine pretreated artery, the major
proportìon was nretaboljsed (87%), althougfi 3U.DOPEG remained as the
principal metabol'ite. These results accord with the welI documented
ability of neserp'ine to inhibjt retent'ion of NA by neuronal vesicles.
The actual retention of unchanged amine in the reserpine-pretrea.ted
artery was probabìy less than the 0.5 nmol .g-1.g0 nrin-i shov¡n 'in Table
3.1, since the tissues were onìy washed for 5 seconds at the end of the
incubation perìod. The extraceilular compartment in this tissue 'is
approximately 0.6nr'l .g-1 (cie la Lande et al , i9B0). Hence, approximateìy
54.
0.13 nmol .g-1 of the 3H.l{A remain'ing 'in the t'issue would have resulted
from the distribution of the amjne into the extracellular compartment.
Reserpine pretreatrnent was also associated wjth a considerable increase
in 3H.D()MA format'ion; however, it still represented only a minor
proportion of the total metabolites (LI%) compared vrith 3H.DOPEc (48%).
The marked i ncrease 'in deami nated nretabol'ite formati on w'ith reser-
pi ne pretreatnlerrt accorcis wi th the drugs i nhi bi tory acti on on ves ì cul ar
binding of I.lA, since after its uptake into the axoplasm of the nerve,.
the NA is exposed to intraneuronal deamination by MAO. The marked
predom'inance of DOPEG over D()tfA ìndìcates that deanrination to the
i ntermed'iate al dehyde i s assoc'iated wi th subsequent metabol i sm v j a
the aldehyde reductase pathway, rather than via the a'ldehyde oxjdase
pathway. In this respect the rabbit ear artery resembles a number of
other perÍpheral tissues; ê.g., the cat,nictitating rnembrane
(Langer, 1970), the rat heart (Fiebig and Trendelenburg.'I978 a,b), the
rat vas deferens (Graefe et a1,7973), the rabbit aorta adventitia (Levin,I9l4; Eckert et al, 1976), the dog saphenous vein (Paiva and Gu'imaraes,igZej and the dog mesenteric artery (Garrett and Branco, 1977).
The lack of Ca++ in the bathjng med'ium dìd not mod'ify the above
pattern of uptake and metabolism of NA in the reserpin'ised artery
strips (segments not exam'ined). One qualification is that the
retent'ion of unchanged am'ine tended to be even less in the Ca+'+ free
strips. In view of its sìgnìficance to later studies on perfused
segments rvhere t.he efflux of metabolites is used as an index of thejr
rates of forrnation, the low proportion of unchanged amine plus nretaboljtes
retained in the tissue requìres emphasis. This proportion amounts to only
18% of the total 3iJ. nietabol i tes f ormecl by the ti ssue.
55.
The failure of Ca*+-lack to modify ìntraneuronal retent'ion and
metabolism of unchanged amine undouotedly reflects the neglig'ibiìe
role played by vesicular binding of NA in the reserpine pretreated++artery. Ca" has been shown to be not essential to the cocaine-sensitìve
uptake process by wh'ich NA is transported into the axoplasrn of the
nerve from the extracellular Space. llov¡ever, Ca++ is essential for
uptake and b'indìng of NA in the neuronal vesicles (Trendelenburg, i980).
The absence of an effect of Ca++-lack on O-methyìated metaboljte
formation is somewhat surprìsing'in view of the evidence that the
^^++omrssron oT La decreased the 0-methylatìon of iSO in the rat
subrnaxillary gland by 25% (Maior et al, 1978). Trendeìenburg (1980)
al so found that the omissi on of Ca++ caused a srnal ì si gni f i cant
reduction (by 20%) in the extraneuronal uptake of 3H.NA by the perfused
rat heart wh'ich was both reserpinised and l'140 and C0MT inhib'ited.
The kinetic data sholvs that the amounts of each metabolìte
formed, and the amounts which then effiuxed into the bathing med'ium,
are linearly related to the substrate (3ti.tln) concentration over a
range of 0.018 to 0.18ut'1. Furthermore, ivith the exception of 0i4DA'
these amounts approximate fajrly closely to the rates of fornlation
and ef f I ux of the ì ndi v'idual metabol'ites. Presumably the I i near
relationshjp reflects the fact that the concentrat'ions are well belorv
the Km for neuronal uptake (rabbit aorta 2.3y14; Henseling, 1980a) and
the Km for extraneuronal uptake (rabbit aorta 3.6u14; Hense'lìng, 1980a).
Prazosin was included in a nurnber of the experjments to reproduce
the conditjons ìn perfused artery segments (Chapter 4) where it was
present to prevent the constricbor response to NA. It had littleeffect on the metabolite effluxes, imply'ing that constriction and/or
o-receptor blockade did not 'influence metabolite formation jn the
artery s tri p preparat'ion .
56
The potent ình'ibitory effects of cocaine on metabol'ite effluxes
are consistent v¡ith the earl'ier reports of Head et al (1975) and Head
(1976) that DOPEG and DOMA are largely neuronal in orig'in in this
vessel . However, unl'ike the results of Head et al , a s'ignificant
inhibìtory effect of coca'ine on OMDA formation is apparent in the present
study. The d'ifference may be because Head et al measured only the tissue
levels of metabolites; or alternat'ively it may reflect the different
experimental condit'ions, s'ince Head et al used artery segments, from
non-reserpi nì secl rabb'its, i ncubated 'in Ca++ Krebs sol uti on. The
significance of the inh'ib'itory effects on OMDA efflux and the enhancement
of NMN efflux, are considered in Chapters 6 and 4, respectively.
The selective 'inhibitory effects of hydrocortisone on NMN efflux
impìies that O-methylation of NA occurs by a cortÌcosteriod-sensitive
extraneuronal uptake of the amine 'into a C0MT-containing compartment,
sim'ilar to that shown by Head et al (1980) for the O-methylation of
i soprena'l i ne. Sì nce hydrocorti sone d'id not eff ect 0MDA ef f I ux, i tseems likely that OMDA formation does not involve the steroid-sensitive
extraneuronal uptake of NA; th'is questìon ìs considered further in
Chapter 4.
CHAPTËR 4
3DIFFUSION AND MTTABOLISM OF H. NA
IN PTRFUSED ARTERY SEGMENTS
57.
CHAPTTR 4.
DIFFUSION AND METABOLISM oT 3H"NA IN PERFUSED
ARTERY SEGMENTS
INTRODUCT I ON
This chapter presents the major study of the thesìs, describ'ing
the influence of the surface of entry (e'ither intimal or adventitial)
of noradrenal i ne (NA ) on i ts metabol 'i sm 'i rr reserpì ne-pretreated rabbi tear' arteries. As set out in the General Introduct'ion (Chapter ì ), th'is
study was prompted in the first'instance by the possibifity that the
rel ati ve rates of f ormati on of the metabol i tes of neuronal orig'in m'ight
ind'icate the relative concentrations which either INT or EXT NA achieved
ìn the regìon of the nerve termìna1s, and hence indicate the magn'itude
of the gradient of concentratìon of NA ex'ist'ing between the surface of
entry and the opposìte surface. Furthermore, the study has provided
an opportunìty to explore the regìonal differences'in metabolism of NA
wi thì n the vessel wal I under condi t'ions where the adventi t'i a and medì a
were'intact, as opposed to the stud'ies on the separ"ated adventit'ia and
med'ia of the aorta (described in Chapter l).Also indicated in this chapter are the influences of neuronal
and extraneuronal uptake, and of constrictor tone, on the patterns of
metabolite efflux from INT and from EXT NA. Earl'ier studies from the
author's laboratory, and also in those of Prof. U. Trendeìenburg
reported in part by de'la Lande et al (]980), had shown that D0PEG was
the major metabolite of NA applied to the adventit'ia of the artery.
It was also known that both an inhibitor of neuronal uptake (cocaine)
and an inhibitor of extraneuronal uptake (DOCA),'increased the flux of
unchanged EXT NA 'into the lumen of the vessel . However, the 'influence
of the extraneuronal uptake'inhibitor on the metabol'ite formed from NA
5B
had not been preciseìy defined in this vessel, nor was the influence
of either agent on the netabolisnr of intraluminal NA known. Further,
jt was knovrn that in artery segments exposed to EXT NA, the flux of NA
pìus metabolites (not reported) rvas decreased u¡hen the artery constricted
(Parker,1977;dela Lande et al, 1980). Hence it was ìmportant to take
the effect of constriction produced by 3H.t,lA into account when comparìng
the relative metabolisms of intraluminal and extralumìnal NA. This has
been done ìn the present. study by conrparing the metabolism of INT
and of EXT NA ìn perfused artery segments under three different
experimental conditions which alter the magn'itude of the constrictor
response to'the f'lA, namely (a) in Ca**-fr.. med'ia to m'inin'ise
constrictor activity of NA, (b) in Cå+-free nredja plus prazosin
(an o¡receptor antagon'ist) to eljminate constrictor actìvity, and
(c) in Ca++ rnedia to maximise the constrictor activ'ity of NA.
METHODS
The methods used in the present chapter are described'in detail
in the General l4ethods (Chapter 2). Briefly, reserpìnjsed ear artery
segments vrere perfused at 0.5 ml .min-t (0. in one stucly where the
effect of increased flow rate , 2.0 ml .min-1, *u, considered) with Ca''-+-
free Krebs (or in one study where the effect of Ca++ was considered)
solution at 37oC and bubbled with 95% OZ,5% C)Z. Incubations of 30
minutes duratjon with (-)3H.NA.(0.1BuM) followed at least a 60 minute
pre-incubation period. Any drug trealments were applied 30 minutes
pri or to, and cluri ng , the i ncubati on wi tfr 3U. tlR.
In those stuclies where 3U.ttR was appìied to the EXT surface of
the artery segment, this medium was replaced with fresh substrate at
the 15 minute ìnterval so that the substrate concentration was not
great'ly dim'inished by neuronal deami nation over the 30 mi nute 'incubatì ng
TabLe 4.1 5INT H.NA 59.
The flurx of unchangeO 3H.t'lA and effl'.rx of 3H.metabol-ites into either bathing solution of rabbit ear artery segments i¡rcubatedwith (-)3H.ruÄ, (0.18 ¡rM) applied to the intimal surface.Values shown are means t SEM.
Metabolite Efffux nmol. g-1.30 min-1. NA
DiffusionCoefficientxLO-7 cm?..""-13H. 1"b"1
Treatment(n)
2,5,6-C
7-C
* incij-cates significance5 indicates significance
NAFl-ux
(p<0.0s)(p < 0.0s )
DOMA
EXTDOPEG
EXTNMN
EXT Total INTOMDA
EXT TotaIINT TotdI INT Total INT
compared with Prazosin; unpaired t-test.compared with Untreated (7-C labelled); unpaired t-test.
0"91_lo.t+
o.3210.11
6 .09lL.76
g
4.12to. o¿
L.62lo.2o
;',-
o.a4lo.2r
0.90to. og
0t0
o.46lo.20
0.31to.oB
0.13!0 .01
o.22to .02
o.L2+0.06
lo.I7
o.1710.06
o .47t0.05
o.37lo.07
.24 0.23
.04 10. 05
o,20lo.oz
0.54lo.23
0.18!0.o7
0.36lo.21_
0.53+0.13
0. 18+o.oB
5
0. o9lo.o2
o.07to.02
g
o.24t0.11
0 ,11to. oB
0+0
0.65+0.04
o.o710 .01
o.25lo.o2
0.33lo.02
o.o4to.01
0 .40t0. 03
o.62to.04
U.U5to. 01
o.95+0 .06
0 .9110.1:<
. s8 0.35
.08 10.05
ô+O
0.65t0. t_9
o.21"+o .06
0 .03+0 .01
5
o .44lo.r4
o.32+0.1o
0 .04to. o1
q
.2I 0.11
.o7 10.03
o.01t0.00
E
72o8
o.o710.01
o.75+0.15
o.52i0.13
o.33t0. t_0
o.20t0 .06
o.46 0.t0,05 +0.
o.o2t0 .00
0.50t0.10
o.26t0 .04
o.o5i0 .01_
0.2s+0 .06
0.36+0 .08
o.26to.o'7
0 .10lo.o2
o.23to.07
0.13to. 06
q
o.12+0 .05
0.07t0.06
g
0 .10to.o5
o.o7+o.02
o7o3
0t0
0.1010.05
0.1910.04
0.o5!0"01
o.o7lo.o2
o.72+o.02
0 .08lo.02
0.05to. 01
0. o1t0 .00
0.11lo.o2
0 .06to. 01
o. o7+^ (\t
0.01 0t0.0i t0
5
06o4
0+0
c.09t0.07
0.10t0 .03
0.08!0.07
o.o210.01
0 .06to.os
.o7 0.03
.03 10.01
o.L2+o.03
o.23+0.03
0.96t0.10
0 .39to.06
292A
1
t0.
o.2I10.04
0.10+0. 05
Untreated(n=s )
Prazosin(n=11)
Hydrocortisone(n=7 )
Cocaine(n=5 )
Un+-reated(n=5 )
Ca++(n=5 )
PBZ(n=a)
3 60Table 4.2 EXT H.NA
The fh.ix of uncþanged sH.NA and efflux of 3H.metabol-ites into either bathing solution of perfused rabbit ear artery segmentsincubated with (-)Stt.Ua (O.18 yM) applied to the adventitial surface.Values shown are means t SEM.
Metabolite Efflux nmol. g-1 .5o*in-1 .NA
DiffusionCoefficient
xIO-7 cm2. sec-13H. l-.b.1
7-C
Treatment(n) Total INT Total INT
NAFl-ux II'IT
DOMA
EXTOMDAEXT TotaITotal INT
DOPEGEXT
NMNEXT
2 15 r6-C
j-nd.icates s ignif icanceindicates significance
(p<0.05)compared with Prazosin; unpaired t-test.(p<0.05) compared with Untreated (Z-C ta¡elled); unpaired t-test.
L.2Llo.23i .88
+0.63
6.O410.19
5
5 .00+0.51
I.92+o.34
2.4510.36
4.56lo.43
0.53+o.7/,
o.27+0. 10
o.27lo.o4
0 .63t0.140.55
t0 .07
0.3610.05
o.18+o.L2
o.3210.04
0. 1310.05
0.15lo.o4
o.2410.05
o.23t0 .01
0.13 0 .24 0.36!0.04 10.05 +0.08
0.06+0 .05
E
0 .51_
10.1-5o.74
+0.16
0. 13+0.05
5
o.23+0.03
o.07+ô ô,
I
0+0
3805
0.11_t0.03
0.08+o.02
o.o2+0.01
0.36to.040.58
t0 .04
^oolo.26
o.26+0.05
o.2710.03
0 .6110.19
0.10+0 .02
0. l_L
t0- 01
0.56t0 .05
o.24+0.07
o.0310.01
5
o.24+0 .05
0. r_3+o.o7
o.02+o.01
5
0.11t0.010,06
+0 .01
0 .01+0.01
g
ata
10.311 ,81
+o.20o.48
t0.11
3.33+o.29
2.A6lo.22
0 .11+0.07
2.6Llo.222.24
+0.18
0 .09+0 .07
o.72t0 .08
o.62+0.05
o.0210.01
0.65lo.12
o .40+0.05
0 .03+o.o2
5
2.80lo.4L
2fu
3.4610.53
.26 2.67
.36 !O.40
o.o4+o.02
5
0.01_to.00
5
08o4
L.L7+o.L7
01 0.0800 t0.04
0.99to. 16
0.1_8lo.a2
o.7L+0 .06
0 .61+0.07
0 .60+o. 06
o "52t0.06
0.1110.01
o.08+0.01
0.+ô
o.t0.
37o7
o.02+0.01
5
c.3510.16
o.27+0.11
o.32 0.+0. 07 t0.o.o2
+0 .015
0.06lo.o20.05
to. ot_
0 . u-tO
+0. o0s
o.4510.07
o.47t0.06I.I7
t0 .09
o.79i0.07
o.27lo. 03
o.25!0 .09
1.49lo.2L
5
Untreated(n=s)
Prazosin( n=11 )
Flydrocortisone(n=a)
Cocaine(n=5 )
Untreated(n=5 )
Ca++(n=6 )
PBZ(n=a )
61.
period. Thjs replacement was found to be unnecessary ìn segments
?exposed to Il{T tH.NA where quantitatively less metabol'ism occurred.
The amount of unchanged 3H.tU and 3tl.metabolites were then analysed
by the cascade column chromatographic technìque descrìbed in the
General trlethods (Chapter 2).
Rout'ine measurements of length, dìaneter and r,leight of the
vessels were determjned as described in the Gerleral I'lethods (Chapter 2).
These values allowed the calculat'ion of metabolite formation, expressed
in nmol.g-1.30 m'in-1, and of the djffusivìty of substrate through the
vessel walì, expressed as the apparent diffus'ion coefficjent (in crn2.se.
us'ing the e(uat'ion of Crank (1956) for the di ff tlsion of a substance
through the walI of a holIow cyììnder.
In paralìe1 experiments, the efflux of metabol'ites from 'isolated
artery strips, i.e., where the 3H.NA entered via both surfaces of
the vessel simultaneously, were examined. Each artery strip was derived
from the same vessel used in the perfused segntent studjes and exposed
to identical'incubating condìtjons. The results of the antery strip
studies have been presented in Chapter 3. The relatjonship between
the metabolism in artery segments and strips are considered'in the
discussion of the present chapter and again in the General Discussion
(Chapter 9).
1)
RESULTS
( t) Metabolite dìstrjbution.
The amounts of metabolites vihich effluxed into the intralumìnal
(INI) and extralum'inal (fXf) bathing solutions during sepanate'incubations
with INT or with EXT (-)3H.run (0.1BuM) under a variety of conditions
during a 30 nlinute period of incubation are shown'in Tables 4.I and 4.2
respectively. The total amount of each metabolite lvhich effluxed from
the vessel is shov¡n; this represents the sum of the metaboljtes whjch
62
onl
I
2.0
EXT (-I3H.NA INT (-I3H.NA
12.5.6-C lobelled I
f] uNrneATED ¡¡=51
ffi PRAzostN (¡=11)
r pr<0'05
mubot n9 uso nlot
.T.gÉ,o
(V|.r'qoÉe
01a
tffiLÆ0
1.0
0
rå'*¡DOMA DPG NMN OMDADot'rA DPG NMIJ oMDA
opposite solut ron
I kr..¡ ffiffid,DCh,IA DP6
Ëffi ÊTöNMN OMDA
&øOO¡.IA DPG NMN O,IDA
Fis. 4.I The effect of prazosin (0.2 UM) on the efflux of SH.metabolitesin nmol.g-1.SOmin-l into the Ca++ free medium bathing either
surface of perfused ear artery segments (from reserpinised rabbits)when (-)Sn.Na (O.14 uM) is apptied to either the adventitia (SXt) orthe intima (INT).* indicates significance (p<0.05); unpaired t-test.
63.
effluxed from the vessel and distributed into the INT and EXT bath'ing
solutions. Some of the data in Tables 4.I and 4.2 is also presented
in Fig.4.l to show the pattern of metabcllite effluxes in untreated
(Ca++-free), and ìn prazos'in-treated (Ca++-free) vessels. Although the
metabol i sm of NA i n the prazosì n-treated vessel s differed 'in m'inor
respects from the untreated vessels (described subsequently), in both
vessels the strìking feature 'is the difference between the patterns
of metabolites of INT and of EXt 3H.NA. These differences will be
defined quantitat'ive1y for the untreated vessels incubated with 2,5,6:C
3H. ¡tR.
In the,case of EXT 3H.¡tR the major metabolite was 3H.UOpEe representing
66% of the total metabol'ite efflux; the other metabolites were 3H.OOltR
(14%'), 3H.0MDA (13%), and 3H.Nl¡N (7Ð. unchanged 3H.t¡R comprised 4l%
of the total 3H'in the opposite (ì.e.,iNT) solutìon. In the case of
INI' 3H.NA, the major metabol'ite was 3tt.t't¡,tttt represent ing 37% of the
total metabol'ite efflux, the remain'ing metabolites *uru 3H.DOPEG (30%),
3H.ONOR (27Ð and 3H.DOMA (6Ð. Unchanged 3H.¡lR comprised l6% of the
total 3H 'in the opposì te ( i . e. , EXT ) sol ut'ion.
The efflux of total metabolites from segments incubated with EXT
3H.t'tR was 3-fold greater than from segments incubated with INT 3H.ruR,
th'is was due primarì'ly to a 10.4-fold greater efflux of 3H.D0PEG lvith
fXt 3H.trtR. However, the total efflux of 3H.NMN from vessels'incubated
w'ith EXT 3H.t¡R was on 1y 56% of that from INT 3H.ttR. Surpris'ingìy, the
flux of unchanged 3H.¡tR across the vessel wall was 2.3-fold greater
than that of INT 3H.ttR as indicated by d'ifferences ìn apparent diffus'ion
coeff ic'ients of 1.92 and 0.84 cm2.sec-'l respectively (Tables 4.1 and 4.2)
As 'indicated by their relative distributions between the INT and
EXT solutìons, the relatìve.effluxes of the metabolites from the two
surfaces were influenced in different ways by the surface of entry of
64
TabLe 4.3
Relationship between perfusion pressure and walf thickness in reserpinisedrabbit ear arteries incubated with either INT or with EXT (-)3H.1¡e (O.fA pf'l¡in Ca++ and Ca++ free medium.Va1ues shown are means + SEM.
Treatment nIncubatingsolution A P(mm HS)
Wa1I thickness (mm)
relaxed constricted A
Ca++ free 9r4
9r4 EXT
INT 13 t5
0
0.1LiO.04 0.1610.01
o.11 0.04 0.11 0.o4
0.os
0
EXT
INT 66 130
10 +6
o. 1 310. 02 0. l-810. 01
o . 1510 .02 0 .l-510 .02
0. 05
a.o2
Ca++ 6r4
6r4
65.
3tt.trlR 'into the vessel wall. As shown in Figs. 4.1 and 4.2 the efflux
of 3H.DOPEG into the EXT solution was 2 to -fold greater than jnto
the INT solution irrespective of the surface of application of the
ami ne . I n contras t, the ef f I ux of 3H . ttt'¡tl vras approx'imately 2-f ol d
greater from the surface exposed to the 3H.NA than from the opposite
surface. The relative effluxes of 3H.OMOR were relatively independent
of the surface of entry of 3H.t'{R.
Although the above findings are based on'ly on the total amounts
of metabolìte which effluxed from the tissue during a 30-minute
period of incubation with 3H"NA, the kinetic data from the artery
strips (pres'ented'in Chapter 3) in¿icated that these amounts prov'ide
a reasonable estimate of both their rates of formation and rates of
efflux from the vessel during this period. Hence the precedìng results
po'int to two distinct types of effect whìch the surface of entry has
on the rnetabol j sm of 3H . t,tR, namely , ( 1) i t determi nes the rate of
formation of the deaminated catecholamìne metabolìtes but has only a
minor effect on the'ir relative rates of efflux from the two surfaces,
and (2) it has a smal ler effect on the rate of 3H.ntqtl format'ion, but
determ'ines the direction of efflux of this metabolite from the vessel.
(?) Constrjction.
In the vessels incubated jn Ca++-free r¡ed'ia described above, EXT
.)
"H . NA (0. i8uf'1) di d not i nf I uence the external di ameter or perf us i on
pressure; however, there lvas a persistent small cpnstrictor response
during incubations with INT 3H.ltlR (0.iS.uM) as'indicated by a mean
increase in perfusion pressure of 13 mmHg (Table 4.3). Hence in such
vessels the metabolism of EXT and of II,IT 3H.ttR were not compared under
identjcal condìtions, the metabolìsnt of EXf 3H.NA referring to
66.
relaxed (thinner walled) vessels, and that of INT 3H.trtR to constrìcted
(thicker walled) vessels. To determine the 'influence of the constrictor
response of the vessel on the metabolism of 3H.NA, two types of experì-
ments were carnied out. In one, the metabolism was compared ìn
prazos'in-treated (Ca++-free) vesse'ls, i.e., where the constrictor
response was abolished, and the other where Ca++ was included ìn the
bathing media to enhance the constrictor response.
The effects of these treatments on the metaboì'ism of 3H.NA u.u
summarised in Tables 4.1 and 4.2, and Fìg. 4.1. Since 2,5,6 3H.NA *u,
used in the prazos'in and Z 3H.NA in the experiments with Ca++, the dataf,f
on Ca"-free untreated vessels are separated accord'ing to the type of
label e*ptoy.O. However, it will be seen ìn Tables 4.1 and 4.2 tha+.
the type of label d'id not influence metabolite effluxes to s'ignificant
extents, and for this reason, the two sets of data on Ca++-free
untreated segments were pooled to assess the s'ign'ifìcance of the treat-
ment effects.
In ca++-free vessels 'incubated with EXT 3H.t'¡R, the most pronounced
effect of prazosin was a tendency to decrease the total effluxes o'F
3tl.OOpEe and 3H.OMDA; however, ne'ither effect was sìgnìficant. In
vessels incubated with INT 3H.tlR, prazosin tended to increase total3H.uoprg eff lux and total 3H.t¡l,ttt eff jux (by 50%); however, only the
effect on 3H.NMN efflux was sign'ificant. Prazosin was without effect
on the flux of fXt 3H.NA across the vessel waìì, but tended to increase
the flux of t¡lt 3H.t',tR. Although the later effect failed t'o reach
significance (0.1 < p < 0.5), 'it is probably a genuì.ne effect, sìnce
the d'iffus'ion coefficient of Il'lT 3H.t¡R was unaffected by prazosìn
despi te a s'ign'if icant decrease i n wal I thi ckness .
The effects of repìacìng Ca++'in the Krebs solution are shown ìn
Tables 4.1 and 4.2, and in Fig.4.2. It should be noted that these
experiments with Ca++ treated vessels were technicallv difficult to
67.
3.0
2'O
1.0
EXT (.I3HNA INT I.}3H.NA
f 7-C tobe[ed I
.1cËo
(v,
r'f'0ctloEc
Ëñ
ircuboting solution
opøita solution
tr UNTREATED (n=51
N con'-KREBS ¡¡=61
DCMA OPO NMN G4DA
..ÑNfufu0DC}4A DPG NMN OMDA
0 rKOæIA DPG
rì*. ÜñNMN CN4DA
å*fufufuOO.IA DPC NMN OMDA
Fig. /* .2 The effect of Ca++ in the medium on the efflux of 3l{.metabolitesin nmol.g-1.3Omin-1 into the solution bathing either surface
of perfused ear artery segments (from reserpine pretreated rabbits) where(-)sH.f.¡e (O.fe ut{) is applied either to the adventitia (EXf) or to theintima (INT). Untreated segments had no Ca++ in the bathing media.
++
J H.NA and the efflux of 3
(-)3n"rua (o.t-BuM) . valuesfor Ca++ samples.
68.
H. metaboli+u€sfor Ca++ free
Table 4.4 Ca treated vesselsThe ef f ect of replacing the Ca++ in the medium on the f- l-ux of unchangedin perfused rabbit ear artery segments incubated with either INT or EXTsamples are combined data from 7-C and 2,5,6-C labelled NA; and 7-Ç onlyVal-ues shobrn are means t SEM.*- indicates significance (p<0.05); unpaired t-test.
Metabolite Effl-ux nmoL 3Omin-1
IncubatingSol-ution
Treatment(n)
NA
F1ux INTDOMA
EXTDOPEG
EXT
-1. g -.
NMN
EXTOMDA
EXT TotaITotal INT Total INT TotaÌ INT
NA
DiffusionCoefficientxro-7 cm2. =".-1
0. 78t0.16
o.32+0.11-
1. 56lo .23
8863
1to
o.33+0.l_3
0. 50lo.t4
o. 15+o.o4
o. 09to.o2
o.24+0.11
o. 35to. 13
o.24 0.to.05 lo.
5608
0.69+0. 10
o.4910.09
0.13to. 04
o. 19t0 .03
o. 65t0.09
o.32+0.10
;L
o.2910.06
0.11+0.05
o.42t 0.03
o.2tto.07
0.18 0.lo.o7 +o.
2/,o7
0.56+0. 03
o.25to.c3
0.06+0 .01-
0.11j0.01
o.23t0.07
o,44+0.08
o.29to.o6
o.L2t0 .03
0. 15to.03
0.10+0.05
3.39lo.29
2.67+o.40
2.7L+o.22
2.42+0.18
o .63+0.05
0 .,iOt0 .05
o.1c+0.0.3
0. t_0
t0"03
0.05+0.03
0.0510.01
0.0710"05
o.o4+0 .01_
o.5410 .07
o.37lo.o7
o.43t0.oB
o.32t0.07
0.05+0.01
0.09to.0t_
0. 16+0.03
o.1010.05
o.36+0 .05
o.25+0.09
c-**(n=5 )
++Ca
( n=1 0)free
^++UA(n=6 )
Ca++
(n=lC)free
INT 5H.NA
EXT 3g.na
69
carry out, and a number of arterìes had to be rejected when the INT
3H.l,lR caused an excessive rise in perfus'ion pressure (greater than 150
mm Hg). in two experiments thìs difficu'lty was c'ircumvented by reduc-
ing the concentrat'ion of 3tt.ttR so that the increase'in perfusion
pressure was within the desired range (50-100 mm Hg); in v'iew of the
ììnear relationship between metabolite efflux and substrate concen-
tration in the studies on strips (Chapter 3), ìt was cons'idered
justifìed to adjust the experimentally derived metabolite effluxes to
correspond to a concentration of 3H.¡tR of 0.l8uM.
Repìac'ing Ca++ in Krebs solutìon tended to decrease the effluxes
of al I metabol'ites, 'irrespecti ve of thei r surf ace of eff I ux, or the
surface of entry of the 3tt.ttR (Tables 4.1, +.2; F'tg. 4.2). The onlya
except.ion was'H.DSMA efflux during ìncubation with Ittt 3H.t'tR. Hovrever'
the onìy changes vrhi ch were si gn'if i cant (when compared wì th the pool ed
data on Ca++-free untreated vessels) were as follows: (a) durìng
i ncubati on w'ith EXT 3H
. t¡R, decreases 'in total eff I ux of 3H . QMDA, and
ìn the effluxes of 3H.NMN and 3H.OOpge from the'intimal surface, and
(b) cluring'incubation with l¡lt 3H.NA, the decreases'in both the total
effluxes of 3H.NMN and'its efflux from the EXT surface. Although the
fluxes of EXT 3H.t'lR and INT 3H.ttR were also less ìn Ca++ than in the
Ca++-f ree vessel s, the dì f f erence bei ng part'icu'l arly nrarked i n the case
of INT 3H.NA, these differences were not stati st'ical'ly sign'if icant.
Assum'ing that the above effects of pnazosin and of Ca++ were
related to'their effects on the constrictor responses to NA, the
preceding find'ings imply that constriction is assocìated primariìy wìth
a decreased efflux of 3H.trlNtl, part'icu.lar'ly from the INT surface, and
in the case of rxt 3H.NA, with a decreased efflux of 3H.D0PEG from the
INT surface.
70.
EXT FI3H NA INT (.)3H.NA
12.5,6-C lobelted )
I col'{TRoL Ín=3 )
ffi cocarNE (n=3,5)
r p<0'05
incuboting solution
TC.E
ofFl.I
ctt
oEc
I
2.0
1.0
ût
û
Ætu Lffifu
0 -ÉrDCX"IA DPG NMN OMDADOMA DFG NMN OMDA
ePPOSo tionUsol
t
0 å*DOþ14
aÃ5D0û,1¡ADP6 NMN OMOA DPC NMN OMDA
FiS. 1.3 The effect of cocaine (29 tM) on the efflux of 3H.metabotitesir¡ nmol.g-1.3omin-1into the Ca++ free mediurn bathing either
surface of rel-axed (prazosin, O.2 UM) perfused ear artery segments(from reserpine pretreated rabbits) where (-)3H.1¡¡, (O.18 uM) is appliedeither to the adventitia (SXf) or to the intima (fnf).* indicates significance (p<O.05); unpaired t-test.
7r.
(3) DOPEG formation ratio.
Since stud'ies on artery strips presented'in Chapter 3 sholved that
3H.OOpEO formatìon was linearly related to substrate concentrat'ion, and
as shown subsequentìy, that 3H.D0PEG was ìarge'ly neuronal in origin,
then the rat'io of the amount of 3H.DOPEG formed from EXT 3H.tttR to that
formed from I¡tt 3H.NA (termed the DOPEG fornrat'ion ratio) should indjcate
the ratios of the concentrations INT and EXt 3H.tlA achieve in the region
of the nerve termi nal s.
I n the rel aied (prazos'i n- treated ) arteri es thi s rat'io was I ow
(4.4 I 0.5), in the untreated Ca*+-free vessels lvhich constrìcted
slightly to'INT 3H.ttR ìt was 3-fold greater (10.4 ! I.7) and in theII
Ca---treated vessels it was 6-fold greater (23.6 + 11.4). The great
variability in the ratjo in the latter vessels may have reflected the
difference in the magnitude of the constrictor responses of indìv'idual
vessels, since the vessel lvith the hìghest rat'io of 63 also showed
the greatest constrictor response (120 nrmHg).
From the results'in Tables 4.I and 4.2, ìt r^lill be evident that
the increases in these ratios in the more constrìct.ed vessels were due
primarily to the decreased rate of 3H.DOPEG efflux from INI' 3H.NA,
rather than an increased rate from fXf 3H.trlR.
(4) Neuronal and Extraneuronal Upbake Inhibjtjon.
(a) Coca'ine
The effects of cocaine (29uM) and of hydrocortisone (413u11)
were examjned to provìde an ìnsight into the influences of neuronal and
extraneuronal uptake processes on the d'iffering patterns of metat¡olite
formations from INT and from EXT 3U.HR. The effects were studied in
relaxed (prazos'in-treated) segments bathed'in Ca++-free med'ia. The
results (faOles 4.1 and 4.2 and also Fì9.4.3) indicaied that in
72.
arteries incubated with tXT 3H.run, coca'ine signifìcantly decreased the
efflux of 3H.DOPEG and 3H.DOMA by 96% and 87% respectiveìy, and'increased
the efflux of 3H.t'ttlt'l by 2.6-fold (s'ignìficant only in t.he case or 3H.t'¡Mtt
effluxing ìnto the INT solutìon). A decrease'in 3H.OMDA efflux by 35%
resulted from a s'ignificant
EXT solution (considered in
and also in Chapter 6)
Coca'ine also decreased
app'lied to the INT surface;
decrease in jts efflux (by 50%) into the
more detail later in the present chapter
3H.oopue efflux by 90% when the 3H.NA ,,u,
th'is effect was manifested by decreased
rates of efflux of the metabol'ite'into both the INT and the EXT solutions.
Cocaine also significantly decreased 3H.OOtqn effIux, but only into
the EXT solútion. Cocaine was witl'rout effect on 3H.NMN and 3H.o¡¡oR effluxes.
Based on est'imates of the d'iff usi on coef f i ci ents , cocai ne al so
exerted quantitatìvely dìfferent effects on the fluxes of EXT and of)
INT "H.NA, the former being'increased by a factor of 1.9 and the latter
by 4.6. The net effect of these increases was that coca'ine elim'inated
the differences between the fluxes of EXT and of INT 3H.run, and wìth
one noteworthy except'ion, i t al so el 'imi nated the d'iff erence between
metabol'ite effluxes 'in se3rnents incubated with EXT or lv.ith tl,li 3H.fitA,. The
except'ion was that i n coca'ine-treated segment, 3H. NMN sti I I ef f I uxed
at a more rapìd rate (1.6-fold.) from the surface to whjch the 3H.ttR
was appì'ied.
From these results it was concluded that 3H.oOpee and 3H.D0MA
were largely neuronal in orig'in 'irrespective of the surface of entry
of 3H.NA ancl that this factor was responsible for their more rapid
effluxes into the EXT solution and for the'ir higher rates of efflux
i n vessel s i ncubated wi th EXT 3H. trtR.
73.
EXT (-}3H.NA INT (-)3H NA(2,5,6-C lobelted )
f, coNTRoL (¡=/')
@ uv anocoRTl soNË ln= t,,71
r p<0'05
tionsolutingncubo
2-0
T.cEc¡-(Y)1
Tcrì
oEc
a
DOMA DPG NMN OMDADq\44 OPG NMN qqDA
DOMA DPG NMN Ot,tDA
UM ÆM tu0
1.0
PPoslo tionsoluet
0 ø d.M ft"wDCÐ,íA 0Pû NMN Olt{DA
Fiq. 4.4
medium bathing either surface of relaxed (prazosin 0.2 irM) penfusedear artery segments (from reserpíne pretreated rabbits) where(-)3H.un (o.ra ul¡) is applied either to the acventitia (gxi) or tothe intima (r¡¡r).* indicates significance (p<0.05); unpaired t-test.
The effect of hydrocortisone (¿fS_ptrt) on the effLux of3H.metabolites in nmoL.g-1.3Omin-f into the Ca+{' free
74.
(b ) Hydrocorti sone
Hydrocorti sone (413LrM) i nhi bi ted the f ormati on of 3H. Nlqru *i th
EXT or with INT 3H.¡ln by 7I% and 93% respectìveìy; the inhjbit'ion was
equal'ly marked in the efflux of 3H.NMN'into both bath'ing so'ìutions.
As shown in Tables 4.1 and 4.2 as well as F'ig, 4.4, it was associated
with a small but signìfìcant (1.8-fold) increase in the NA diffus'ion
coefficient w'ith Itttt 3H.NA, rrrith no significant change in the EXT
3H.t'lR diffusion coefficient. The lack of an effect on the efflux of
the other metabol 'i tes 3H. DOPEG, '*. D0l,1A and 3H.¡t',tOR ìmpì ì ed that
their formation was independent of a steroid-sens'itive pathlvay,
The 3ttiOOpfg fornration ratio of 3.1 r¡ras lowest in the hydrocortisone
treated segments (compared with other segrnents perfused at 0.5 ml.min-1,
when the deaminating pathway was available). Th'is low ratio reflected
a tendency for the rate of efflux of 3H.DOPEG from EXT 3H.t¡R to decrease
rather than for the rate of its efflux from INT 3H.tlR to increase.
The failure of hydrocort'isone to increar.3H.D0PEG efflux fronl It'¡t 3l't.ttR
lvas surprìs'ing since'its effect on 3H.NMll efflux and on 3H.NA flrrx
indicated that it hacl eliminated extraneuronal sites of loss of 3U.ttA
in the artery wall. This result may poss'ibly reflect a partial
neuronal uptake inhibiting action of hydrocortisone (as also suggested
in Chapter 3 'in artery strips).
In summary, wh'ile confirm'ing the extraneuronal orìgin of 3H.NMN,
the effect of hydrocortisone failed to reveal any dramatic role of
extraneuronal O-methylat'ion in influencing the patterris of the rema'ining
metabolite formations and distributions in segments incubated with Il{T2
or wìth EXT "H.NA.
75.
-.é f*1åDOMA OPG
ûI
NMN OMDA
EXT (.)3H.NA
DOMA DPG
INT (.)3HNA
( 7-C tobetled I
incubotirg sotution
! uurneotts 1n=41
El PBz (n= 4)
r p<0'05
rü
a
DCF4A OPG NMN OMDA
3û
onopposite soluti
1.0
0
$ d.ruNMN OMDA
rutu"Ëå-DOMA OPG NMN OMDA
Fis. 4.6 The effect of phenoxybenzamine (PBZ, 93 ulvl) on the effluxof 3H. metabolit.s in nmol.g-1 .Sotnin-I ir',to the Ca++ free
mediu¡n bathing either surface of ear artery segrnents (from reserpinepretreated rabbits) where (-)3H.NA (o.18 uM) is applied either to theadventitia (pXt) or to the intima (INT).* indicates significance (p<0.05); unpaired t-test.
Table 4.5 INT PLUS EXT3".*o
The efflux of SH.metabol-ites from rabbit ear artery segments incr.rbated with (-)the vessel simutaneously in Ca++ free medium with prazosin (O.ZU¡A).Va1ues shown are means + SEM.
'k indj-cates significance (p.0.05)i unpaired t-test.
76.
H.NA (O.18UM) applied to both surfaces of3
H-labeITreatment
(n)DOMA
EXT Total3
Metabolite EffluxDOPEG
INT EXT Total-
nmor.g-1.s0 min-lNM
INT . EXT Total rNT
OMDA
EXT TotalINT
o.za 0.+o.03 +0.
;k
0i0
50o5
1.16to. os
0.58!o. os
.41 0.72
.o4 +o.o20.65 l_ .30
10.10 to.08
0.85 L.7810.03 to.06
0 .65t0 .03
o.92t0 .04
3.05lo.r7
0.1910.06
2.42+0.16
o.72t0 .05
o .6110.04
0.07+0.03
o.54+o.L2
o.l7+0 .01
O./.510.10
0. l_0+0.01
0 .09t0 .03
o.07+0.o0
prazosin(n=4 )
Cocaine(n=4 )
2,5 r6-C
77.
EXT l-l3H.NA , plus ¡NT (.I3H.NA
(2,5,6-C lobelted )
I corurnot ¡¡=4)
ffi cocatrue (n=4)
* p<0'05Tc.E t
810.ictloEc
t it
f=f,,È¡
OOMA DPO NMN OMDA DOMA DPG NMN OI-'IDA
The effect of cocaine (29 UM) on the efflux of SH.metabolitesin nmol.g-1.3Omin-1 into the ca++ free medium bathing either
û
ffi0
surface of relaxed (prazosin 0.2 pM) ear artery segments (fromreserpine pretreated rabbits) where (-)3H.iva (0.18 FM) is applied
Fiq. 1.7
both to the adventitia (EXT) and to the intima (f¡¡f).Flã¿i-cates significance (p <olõ5) ; unpaired t-test.
78.
(c) Phenoxybenzami ne
The effect of phenoxybenzam'ine (pgZ) treatment (r^rhìch inhjbits
both neuronal and extraneuronal uptake pathways as vlell as antagonisìng
cx-receptors) on the efflux of metabolites and flux of'arnìne was examjned
in vessels incubated in Ca++-free nledia r^r'ith EXT or with Il'tl 3H.t'tR
(0.tguN). These results are also presented in Tables 4.1 and 4.2 as t^iell
as 'in Fig. 4.6. It can be seen that PBZ-treatment was assoc'iated
with marked reductions in the effluxes of each of the metat¡olítes
regardless of the surface of entry of the amine such that the total
metabolite efflux w'ith ttttt 3H.t'tR or with EXT 3H.t'tRt¡ere reduced by
B0% and 95%'respect'ive'ìy. This was assocìated with marked increases
in the diffus'ivìty of I'lA by 6.4-fold and 2.4-fo1d, for Il'lT and for EXT
a
"H.NA respect'iveìy. In a similar manner to cocaìne, PBZ el'im'inated
the dìfference in flux of amine when applied to either surface of the
vessel.
(5) Gradient of concentration.
In the preceding experiments 3H.l'tR was applìed to only one surface
of the artery segment. Hence the concentration of the amine was tlot
uniform lvithin the vessel wall, but declined between t.he surface of
entry and the opposite surface. To exanline the influence of this
gradient of concentration on ntetabolisr¡ of 3H.tttR, segntents were stuclied
where the amine was applied to both surfaces silnultaneously.
Theoretically, the concentration of NA in these segments should be
unjform throughout the vessel wall. In the four vessels examined, 'it
can be seen from the results (faUle 4.5 and Fìg. 4.7) that, in the case
of 3H.D9pEG and 3H.D0l4A, their respectìve effluxes into the INT and EXT
solutions vJere little different from those segments 'incubated tvith EXT
3H . trtR al one. Thi s resul t i n¿i cate,l that the gradi ent of concentrati on
79
Table 4.6
A comparison of total 3H.metabolite efflux when 3u.w¡ (0.18 pM) is applied toboth surfaces simutaneously, or to ei-ther the INT or the EXT surfaceseparately, of perfused rabbit ear artery segments.Values are means t SnU.
Metabol-ite Eff.].ux nmoL. g-1.30 min-1 .fncubatingsolution
Treatment(n) DOMA DOPEG NMN OMDA
o.72to. oB
2.46lo.22
3 .58!o. go
0.95to .06
o.38lo.o4
L.33to.09
o.47to .05
0.55to .07
t.o2+0.11
Prazosin(n=11- )
Prazosin(n=11 )
7308
ot0
o.L2+o.02
o.61+o.o7
1 .3010.08
1 .1610.03
INT (a)
EXr (b)
(a) + (b)
INT and EXT Prazosin(n=4)
0+O
54T2
3.05lo.L7
Cocaine(n=5 )
Cocaine(n=3 )
0.o8+o.o2
0. o8to. 04
o.16to. 06
o.07to. o1
o. l_l_
to. oi-
0.18lo.oz
0 .91_jo.1g
o.99xo.26
t .901o. sg
73L4
o10.
o.37lo.o7
0.36lo.oz
o.L710 . ol_
0. t_9
to. 06L.78
to,060.58
to. os
(c) + (d)
INT and EXT
INr (c)
EXr (d)
Cocaine(n=a )
80
Table 4.7 IT'IT OR EXT NA ( 2.0 ml . ^irr-1 )
The effect of increasing the fl-ow rate to 2.0 mI. min-1 on the flux of unchanged 3H.Ue and efflux of SH.metabol-ites intoeither bathing solution of perfused rabbit ear artery segments incubated with (-)sH.¡¡A (0.18 ¡rM) appJ-ied either to the intimalor to the adventitial surface of the vessel.Values shown are means t SEM.*- indicates significance (p<0.05); unpaired t-test.
3H
NA
Flux INTDOMA
EXT Total
_19-I{MN
EXTOMDA
EXT Total
MetaboliteDOPEG
INT EXT
Effh¡x nmol-
TotaI INT
5O min-1.
TotaI INT
NADiffusion
CoefficientxLo-7 cm?. sec-1
Incubating TreatmentSol-ution (n)
INT 3H.NA
EXT 3H.NA
232I
1t0
1+0
0806
0.35 0.+0.01 to.
E/
030.19
+0.03
o.13 0.+o.04 +0.
45o9
o.32to. 05
0.85lo.L2
o,51+o.02
1.36to. t-1
o.r4+o.01
o.33lo.o2
o.4710. os
o.72t0 .01
l_.09t0 .06
o.37to.06
0 .68 2.30 2.98!0.06 t0.l_5 lo.20
0.15+0 .03
0.08lo.o2
o.o7lo.o2
o.46t0.02
0.55lo.o2
0.09t0.00
O
t05/o4
0.38J0.03
Untreated(n=5 )
Untreated(n=4)
8t.
3 EXT(-}3H.NA ¡NT F)3H.NA
12.5,6-C lobetled )
solution
I ennZ or*.*¡n-l ¡n=111
ffi fnnZ z.oml.nin'1 lre3,ôl
r p<0 05
t nincubo
1
T.EEctCN
IcÐ
oEc
2'0
0
1'0
F'i s. 4.a
t
.
æDOMA DPG NMN OMDA DOMA DPG NMN OMDA
ri
rl*ìD0"tA DPO NMN ü,404 DOMA DPO NMN OMDA
The effect of increased flow rate (to Z.Om1.min-1) on theefflr-rx of SH.metabolítes into the Ca+-F free medium
onsolutoPpæ¡te
.-{.t
a
s
0
bathing either surface of relaxed (prazosin,0.2 UM) ear artery=.g ".rl=
(from reserpine pretreated rabbits) where (-)3n.NA (0.18 uM)is applied either to the adventitia (EXT) or to the intima (INT).* indicates significance (p<0.05); unpaired t-test.
82
vJas not the primary factor responsìble for the greater efflux of
these metabolites into the EXT solut'ions in vessels incubal"ed w'ith)
EXT (or INT) "H.NA. It also inrplied that the concentration ivhich EXT
3H.tlR atta'ins in the region of the nerves is close to the uniform
concentration achieved throughout the vessel wall v¡hen the amine is
appf ied to both surfaces; thjs is consistent with the rapid diffusion
of NA through the adventitia (see Discilssion).
To determine the influence of the gradient of concentration on
extraneuronal formation of metabol'ites, the above experiments were
repeated jn the presence of cocaine. As shown jn Table 4.6 the total
efflux of e¿ích metabolite in the vessels'incubated v¡ith INT plus EXT
)"H.NA jn the presence of cocaine was twjce the efflux from segments
where 3tl.¡ln vras appliecl separately to either surface. However, unljke
its distribution in the latter segments,3H.NMN (as well as the other
metabolites) was now uniformly distributed between the INT and EXT
solutions. These results indicated that the concentration gradienL of
3H.¡ln within the vessel wall has a major influence on
3H.tlMi,¡ formation and on its relative effluxes from the two surfaces o'f
the artery.
(6) Infl uence of f lolv rate.
The metabolism of (-)3ti.run (O.tgplt) was exam'ined in four artery
segments where the flow rate was 2.0 nrl.min-l instead of 0.5 ml.min-l useci
ìn all the preceding experiments. As shotvn in Table 4.7 as well as
Fig. 4.8, the increase in flow rate u¡as wjthout effect on the amounts
of 3H.DOPEG, tn.D0l'14 and 3H"tt¡,ltt which effluxed from the two surfaces
of the vessels inculrated with EXT 3H.tttR;, the exception v¡as that propor-)
tionally 'ìess 'H.0MDA effluxed from the advent'itial surface at the
higher flow rate. In contrast, 'in segments incubated with INT 3H.NA,
the effluxes of all nletabolites, with the exceptìon of 3H.O¡4OR effìuxing
83
-i.sEo
fV,
5'qoEc,
1'0
1'0
tNT 3H.ru1 (0.1Sr¡M l
! co** (n=5)
ffil co'* - f ree (n=10 )
Ø h*' -free rPRAZ ln=11)
E co**-free +PRAZ 2'0ml.min-1 {n=¿}
incuboting solution
flttr+'¡*tDOMA DOPEG NMN OMDA
opposite solution
-#OOMA DOPEG NMN OMDA
0
0
Fis. 4.9
bathing either surface of perfused ear artery segments (frcnr reserpinepretreated rabbits) where (-)SH.NA (0.18 FM) is applied to theintima (INT). This data is also shown separately in preceding figures.The wall thickness is greatest for the Ca++ studies (O.18mrn) andleast for the Ca++ free prazosin vessels where the flow rate was.
2.OmI.min-1 (o.osnun) .
The influence of decreasinq wall thickness on the effluxof 3tt.metabolites in nmol.g-1.so*itt-l into the medium
84.
from the'intimal surface, were increased by 40-50%. The net effect
was that the DOPEG formation rat'io lvas decreased from 4.4 to 2.7.
Desp'ite the ì ncrease 'i n INT 3H.run metabol 'i sm, the total metabol i te
efflux fr'om EXT 3H.l,tR was still 40% gr eater than from INT 3H.tlR.
However, the difference between the fluxes of tt¡l 3H.NA and fXt 3H.ttR
was much less ev'ident than at the lower flow rate, due to the increase
in flux of unchanged It'lt 3H.NA and a decrease'in flux of EXI 3H.t'tR.
The effects of the higher flow rate on metabolite effluxes from
vessels incubated w'ith INT 3H.ttR are summarìsed 'in F'ig. 4.g. The
ef fects of prazos'i n, and Ca++ are i nc I uded f or compari son . It w'i I I be
seen that the effluxes of NMN and DOPEG in Ca++ med'ium increased
progressi veiy wi th the omi ssi on of Cu**, the addi ti on o'l' prazos'in,
and increasing the flow rate. Interest'ìngìy, these increases
approximately paralìe1 those ìn the fluxes of INT 3H.t'lR (from
Tabl es 4. I and 4.7 ) .
DI SCUSS I ON
(I) ORIGIN OF METABOLITES.
The results confirmed earl'ier evidence that DOPEG and D0MA are
I argely neuronal i n ori gì n and that NMN i s I a.rgely extraneuronal 'in
orig'in in the rabb'it ear artery (Head et al, 1980; de la Lande et al ,
.1978). The results further ind'icated that the surface of entry of NA
does not influence the origins of these metabolites; th'is was apparent
from Fìnd'ings that cocaine strongly'inhibited D0PEG and DOMA efflux,
and hydrocort'isone strongìy ìnhìbited NMN efflux, irrespective of
whether the segments were incubated with INT or eXt 3H.¡lR. The OMDA
fractjon appeared exceptional, in that cocaine s'ignìficantìy decreased
ìts efflux into the EXT solut'ion when ìncubat.ed with EXT 3H.trlR, but not
85.
from Iruf 3H.t,lR. A possìbìe expìanation is presented in Section (5)
of the present dì scuss'ion (and al so exam'i ned 'i n greater detai I 'i n
Chapter 6).
The more rapid efflux of DOPEG and DOMA from the.adventitia was
also independent of the surface of entry of NA, since it was apparent
in segments ìncubated with INT 3H.¡tR, EXT 3H.NA,and INT p'lus EXT
3H.t¡R.
This finding is consistent with evidence that the sites of origìn, i.e.
the sympathetic nerves, are located at the junction of the adventitia
and the nredia, and with evidence u¡hich suggests that the diffusìvity
of NA and its rnetabolites is considerably higher in the adventit'ia
than the media. The evidence stems from the observation in'several
laboratories that during nerve stimulation, 80-90% of the released
transmitter and metabolites effluxes from the adventitial surface
(reyiewed by de la Lande, 1975; Parker,7977). A]though the greater
efflux could also be explained in terms of the proximity of the nerves
to the outer surface of the arteny, there is evidence that (in the
rabbit aorta) tne diffusion coefficient of NA in the jsolated acivent'itja
(4 x 10-6.r2.r..-l¡ i, 5.7-fold greater than that of the isolated
media 0.3x 1a-7 cn.2. r..-l) (Bevan and lörör, lg70; Bevan and Su, lgl3).
Aìthough the d'iffusion coefficients of the nretabolìtes of NA have not
t¡een determined, it is not unreasonable to assume that they are
similar to those of NA in view of their sìm'ilar molecular sizes.
(2) DTFFUST0N M0DEL.
In contrast to its minor influence on the efFlux pattern of2?'H.DOPEG and'H.D0l4A, the surface of entry of the amine exerted a marked
influence on the rates of formatìon of tliese metabolites, the rates
being 3-12 fold greater (depending on the experimental conditions) when
the amine entered via the advent'itja. The lovrest ratio (in vessels
perfused at 0.5 ml.min-1) was in the hydrocortisone-treated arteries,
B6
cc I
0'8
0
1.0
0
<- med iq
0 1
WIDTH OF I^IALL
nervesOdven.-+
2(arbitrary units)
I
3
Fiq. 4.LO A mode 1 of the theoretical gradients of concentratio¡r' across the artery waLl where NA enters either via the
intimal (INT) or via the adventitial (nXf¡ surface. This modelassumes that,(a) the media is twice as thick(b) tne diffusivity of NA in the(c) the watl behaves like the depth of a plane sheet with respect to
the diffusivity of I'lA. i
Hence, this indicates that the concentration of NA at border of themedia and the adventitia (the site of the sympathetic nerves) is20%, or 80%, ì.ower than the concentration at)rsurface where thesubstrate entered depending whether the amine entered via theadventitia, or via the intima, respectively.C= concentrati-on of NA at any point within the wal-I,C1= co.r..ntration of NA applied to the surface.
aå(F,þç. adventitia,¡edia'is twice that in the media, and
87"
and the greatest in the Ca** constricted vessels. The difference
impìies that under steady-state conditions fXt 3U.lrlA achieves a
corresponrli ngìy hi gher concentration than tlttt 3H.NA at the si tes of3H.oOpEe and 3H.D0l4A format'ion, i.e. ìn the region of the nerve
terminals. These differences may also be related to regional differences
in diffusiv'ity since, in theory, the ratio of the two concentrations
would depend primariìy on the relätive distances of the nerves from
the inner and outer surfaces, and on the diffusivity of llA in the
intervening regìons (media and advent'itìa). The relationship between
these two factors ìs illustrated by the model in Fig.4.10. This model
shows that i'f ,(a) the artery wal'l 'is treated as the depth of a pìane
sheet, (b) the media is twice as thick as the advent'itia (as estima.ted
by Bevan and Su, 1974) and (c) the diffusiv'ity of NA is uniform
throughout the vraìì, then the pred'icted ratio of concentrations of EXT
to INT NA at the boundary between the nredia and the adventitia is 2.0.
Hovrever,'if the diffusìvity in the adventitia is twice that in the nredja,ìthe ratio becomes 4.0. The actual ra.tio of the diffusìon coefficients
in either the media or the adventitja of the rabbit ear artery ìs not
known since it is not possible to separate the two reg'ions mechanjcaìiy
in this vessel. However, ìt is probab'le that the value of 1.5 x 10-6 cm2.
su.-l obta'ined by Bevan and Su (Lg74) when l,lA was applied for 10 seconcls
to the intinra refers to diffusivity'in the media onìy. If it is assumed
that the diffus'ivity'in the adventitia of the rabbjt ear artery is
similar to that in the rabb'it aorta (4 x 10-6.r2.r..-1¡, the pred'icted
ratio of the concentrat'ion of EXT to INT NA at the boundary'is 5.3. In
the case of the more analogous moCel of a cylìnder (rather than a plane
sheet), where inner and outer radii are those estìmated in the present.
BB
study (0.29 and 0.41mm, respect'ively), the ratìo will be slightly higher
(6.7). Although thjs ratio is within the range of the experìmentalìy
determjned ratìos, quantitative extrapoìation from thjs model is
probably premature. A puz-zììng discrepancy between the values of the
above diffusion coefficìent in the inner lvall obtained by Bevan and Su
(7974) and a considerabìy lower estimate from our laboratory based on
steady state flux of NA across the whole wall (0.8 x 10-6.*2.r..-i¡
(de 1a Lande et al, 1980) needs to be resolved. Furthermore, one of the
assumpt'ions ìn the model is that neuronal uptake does not influence the
steady-state concentrat'ion of t'lA at the bouncjary betlveen media and
adventjtia. ' Hovrever, the experimentaììy determined rat'ios of concen-
trations were determ'ined from nreasurernents r,¡hich depended on neuronal
uptake of NA (i.e., DOPEG formatjon). If as seerils probabìe, diffusion
of NA is limited in the media compared rvith the advent'itia, it is
possible that the uptake of INT NA, relative to that of EXT NA, is
diffusion-linrited; if so the steady-state concentrat'ion'in the reg'icln
of the neryes will be determ'ined, not only by the concentration gradient,
but also by the flux of INT arnine jnto that region.
Despite these limitations, the model provides a useful basìs wjth
which to ìnterpret most features of the rnetabolic data. The abserrce of
a signìficant difference between the rates of 3H.D0PEG efflux, when
a"H.NA ìs appljed to the EXT surface only and to both surfaces sjmul-
taneously, accords v,rith the predict'ion that the concentration rvhjch EXT
NA achjeves in the reg'ion of the nerves wìll be l'ittle different from
the concentration wlien the latter js uniform throughout the wall and
equal to the concentrati on i n the 'i ncubat'ing sol uti on.
Thi s nlodel al so prov'ides a usef ul bas j s for ì nterpret'i ng the patterns
of extraneuronal rnetabolìte formation and efflux from NA. The efflux
of NMN was 1.9 and Z.5-fold greater fronl the surface of entry of the
89.
INT and the EXT amine, respectively, than frorn the oppos'ite surface'in the
relaxed (prazosìn-treated) preparations. Thjs ratjo is suffic'ient'ly close tc
the theoret'ical ratìo(i.e. 2.0) if it is assunred that (a) the concentrat'ion
of parent amjne decl'ines unìformìy across the media, (b) tne sites of
g-methyìatìon are uniformly distrjbuted across the nledia, but are not
present in the adventìtìa, (c) the rates of O-methylation are dìrectìy
proporti ona'l to the parent ami ne concetrtrati on wi thi n the vessel lvaì ì ,
and (d) the djffusivity of amine and metabolites in the adventitìa
approxìmate to those jn free solution. The theoretical derivation of
this ratio is presented ìn Appendix 1. The observat'ion that the ratio
of 3H.t'tHtt êfflux ('in the presence of coca'ine) from INT p]us Ext 3u.run
was almost exactly turice the rate from Il'lT or fXt 3U.NA separately,
also accords with the above assumptions(a) to (d). Sìnce the present
studies provide ev'idence that NMN formation l'las proportìonal to substrate
concentratì on (Fi g. 3. 1) , and there 'is evi dence (i n the rabb'it aort¡'a )
that C0l,1T activity is uniform throughout the media (Verity et a1 , I97?),
the quant'itat'ive and qua'li tatì ve agreement between tiie t"heoret'ical atld
observed ratio of NMI'I efflux adds consìderable suppot t to the argurnent
that the concentration of parent am'ine does, in fact, decì'ine uniformly
across the rnedia. The onìy quaììfjcation is tlre report by Lowe and
Creveling (1978) that in the rat aorta and coronary blood vessels, C0t4T
activìty, as demonstrated by an immunohistochemical techn'ique, was
confined to the intima. it does not seem possible to reconcile such a
distribut'ion w'ith any of the observed features of the catecholamitte
metabolism'in the present stucly. For examp'le, if COMT'¡rere distrjbuted
.in th'is r1ranner in the rabb'it ear artery, then the surface of 3H.l,tl',llti eff.ìux
should be'independent of the surfaðe of entry of 3H.N¡. It will be
seen from the data presented that cìearìy th'is is not the case. The data
90
presented here for the rabbìt ear artery is in accord w'ith that of
Branco et al (1981a), who showed, using a sensitive autoradiographic
technique that the smooth muscle cells of the rabbìt aorta corresponded
to the stero'id-sensitive extraneuronal 0-methylat'ing s'ite(s).
(3) CONSTRICTION AND FL0r,ü RATE.
In the constrìcted artery perfused at 0.5 ml.min-1, the difference
between the rates of 3H.D0PEG efflux from EXT and from tltt 3H.NA was
more pronounced than in the relaxed artêry. Thus the 3H.DOPEG forntat'ion
ratio was 4.4 i n the rel axed (prazos'in-treatecl) perf used artery, and
II
10.4 ìn Ca"-free vessels in the absence of prazosin, where the artery
was sì'ightly constricted in response to tlt¡t 3H.NA. The rnean ratjo lvas
24 when the constrictor response to INT 3H.t'tR was greatest, ì.e., inaa
the Ca' '-treated arteries which al so constricted to tXT 3H.t'lR. The
increase'in thìs ratio was due largely to a selective decrease'in the
rate of 3H.oopre efflux from INT 3H.tlR. In the presence of prazosìn,
the rates of 3H.DOPEG efflux from EXT and from lttt 3U.NA were increased
and decreased respectìveìy, a'lthough in neither case was the change
sign'ificant. Nevertheless, the possibìlity cannot be excluded that
prazos'in exerted a mild inhib'itory effect on the neuronal uptake and
deaminat'ion of NA wh'ich tended to mask an'increase ìn 3H.OOpfO formation
from INT 3H.t'¡R resultìng from the prazosin inducecl relaxatìon of the
vessel .
Since the rate of 3H.D0PEG formatìon is linearìy related to the
concentratìon of 3H.trtR (Chapter 3), the above f ind'ings 'impìy that the
concentrat'ion which INT 3tl.tttR ach'ieves in the region of the nerve terni'inals
decreases as the artery constricts. Thìs phenomenom can be exp'laìned in
terms ofone or more of the factors (a) to (c) be'low.
(a) Rn'increase'in thìckness of the media, 'if proportìonalìy greater than
that of the adventitia, would steepen the grad'ient of concentrat'ion
of INT 3H.nR between the intima and the nerve terrn'inal region.
91.
(b) Constriction may decrease the djffusivity of NA w'ithin the media.
This possibility seems excluded by the find'ing that, although
prazosin increased the flux of 3H.tlR across the wall, th'is was due
primarily to the decrease in wall thickness; i.ê., prazosin d'id
not alter the diffusion coefficient of the unchanged amine.
Nevertheless, jn an earl'ier study, ìt was shown that the diffusion
coefficient of 14C-.orbitol (which distnibutes onìy in the
extracellular space) was less'in the constricted than in the
relaxed artery (de la Lande et al, i980). Furthernlore, a decrease
in diffusjvity of 3tl.ttR in the constricted artery may a'lso expla'in
the eff'ects of prazosin, and of Ca++, on 3H.NMN efflux from the
vessel . In Ca++ free segments, where on'ly ll'lt 3H.NA caused
constriction, bìockade of this constriction by prazosin was
associated with an increase in 3H.tll'lN efflux from tl,n 3U.NA, but
not from fXt 3H"ttR. This result suggests that constriction of
the artery ìs assoc'iated with a decreased capacity of the artery to
O-meth¡rlate l{A, a suggestion which is supported by the comparisons
I¡etlveen Ca++ ancl Ca++ free perfused segments" The Ca++ segments,
al though constrj cting to INT 3U.ttR, also ccnstri cted to f Xf 3H.ttR.
These effects r{ere associated with decreased effluxes of 3H.NMN in
vessels incubated vrith eìther INT or gXl 3H.nn. The sÍmplest
explanatìon of these findings is that constriction,by decreasing the
cliffusivity of t'lA wìthin the media, reduced the concentration of I{A
available to the O-methylating system .in the vesse'l rvall.
(c) A thrrcl possibility is limitation of entry of INT 3H.tlA into the
vessel r,tall. This nray conceivably result if , for example, the lumen
became convol uted, as the resul t of fol dl'ng of the int'ima, to the
extent that the overlyìng media vvas not uniforinìy exposed. Th'is
possibiììty'is suggested by the find'ing that wherl the resting
92.
perfusion pressure was increased by 'increasing the flow rate to
2.0 ml .min-1, the rates of efflux of all rnetabol'ites during
i ncubati on l.ti th I NT NA, al though not duri ng i ncubati on w j th EXT NA,
was increased. The 'increase in total metabolite efflux at the
higher flow rate was approximately 40%. As a result, the difference
between the rates of 3H.DOPEG format'ion from EXT and from INT
3H.t¡R was Iess pronounced, the DOPEG formation ratio being decreased
from 4 .4 to 2.7 .
At this stage, the data does not permit the contributions of these
factors (a) to (c) to tne metabol'ic changes associated w'ith cottstriction
to be assesSed. However, the results highfight the need for more detajled
morphological studies on the changes in shape of the artery during
constriction, plus further rneasurements of the volume of the extracellulat:
component of the tissue at various levels of constriction.
t4) t.TPTHKE INllIuirIoN.
(a ) Cocai ne
The surface of entry markedly jnfluenced the rate of metabolism
of NA as indicated by an approxìmately three-fold greater efflux of
total metabol i tes ('i . e. , the sum of the i nd'ivi dual metabol'ites ) durì ng
incubatiorr with EXT 3U.¡tR. Cocaine eliminated the influence of the
surface of entry of NA by (a) its ìnhib'itory acùion on 3g.OOpEG and
3H.DONR efflux (already discussed) and (b) bv increasing the
eff'lux of 3H.NMN from Ext 3tt.NA by (2.6-fold} but not from ttrtl 3H.ttR.
The latter observatjon can be expìa'ined in ternls of the locat'ion of the
sympathetic nerves at the med'ial-adventitial junction, so that inhjbìtìon
of neuronal uptake permìts the fXl 3H.NA to achieve a higher concentration
in the unclerlying medìa where the sjtes clf O-methyìation (assumed to be
the smooth muscle cells) are located, but has little effect on the
93.
concentration rvhich Il'lT 3U.t'lR achieves in the media as the amine'is only
exposed to neuronal uptake after ìt diffuses through the rnedia. This
explanation places prìmary importance on the sequent'ial arrangement of
the neuronal deam j nat'i ng and extraneuronal 0-nrethyì ated pathrvays wi th'i n
the artery wall. However, the sequential arrangement cannot explain the
finding that cocaine also increased 3H.NMN formation (although onìy to
a small extent) vrhen the 3H.NA entered both surfaces simultaneousìy
since, theoretìcally, the concentrat'ion of the 3H.l'lA should then be
uniform throughout the artery wall. l-he effect of cocaine under these
conditions is best explained in terms of the tlvo pathlvays acting as
alternative'mechanìsms for inact.'ivating [',14, as proposed by HLlghes (I972)
to account for similar observations on the rabbit vas deferns.
In thg relaxed (prazosin-treated) vessel the flux of unchanged EXT
3H.ttR vras two-fo1d greater than that of ll,tt 3H.trtR. However, ìn the
presence of cocaine the flux of lttt 3H.NA'increased by a factor of 4,
and that of EXT 3H.tt¡R on'ly by a factor of 2.5; hence the difference
between the fluxes is related in some way to the actjvity of the neuronal
uptake system. The estirnate of flux was based on the assumption that the
content of accurnulated amine in the opposite soluticn after the segment
was incubated for 30 minutes with 3H.NA, represents the total amount of
unchanged amine which d'iffused across the artery waì'l in that time.
Hence, it is possible that, in the untreated artery, the flux from INT)"H.NA may have been underestimated due to the metabolism of some of the
unchanged amine after it had diffused into the opposite solutjon and
subsequentìy re-entered the adventitia. Holvever, if this factor was
solely responsible for the d'iffererrce in fluxes of INT and of EXT 3H.NA,
it would mean that at least two-thirds of the amine which reached the
opposìte solutjon undenvent metaboljsm, whereas the proport'ion of
94.
)EXT "H.NA (0.18uM) metabolised during this perìod was only 20%- As
indicated by the stud'ies on artery strips (Chapter 3), the proportion of
3H.tlR metabolised remained the same at a ten-fold lower concentration
of amìne. Hence the assumpt'ion involved jn est'imatin$ the flux ìs
unìikely to account for the 2.5-fold greater flux of fXf 3U.ttR.
A second possib'il i ty is that propor t'ional ly more Iruf 3H.NA than
fXt 3H.NA was removed by neurona'l uptake as the arnjne fluxes through
the region of the nerve terminals. The nragnitude of the increase ìn
flux of unchanged amine produced by cocaine implies that, in the case
of INT 3H.run, 80% was removed in th'is way, and that, jn the case of)
tXT 3H.NA, the proportion was 40%. The INI 3H.NA which was removed
appears to have been converted ent'ireìy to 3H.DOPEG and 3H.D0l'14 sjnce
in the coca'ine-treated segments the increase jn the content of
unchanged amjne'in the EXT solution was approxìnrately equal to the
decrease ìn total flux of 3H.DOPEG and 3H.DOl,lA. it is difficult to
account for the apparently more efficieni removal of ltlA by neuronal
uptake when'it dìffused from the internal surface except in terms of
the possib'ility, considered alrea,Jy, that the renloval of INT 3H.t',lL
by neuronaì uptake js more diffus'ion-lìmited than the removal of F-XT
3H. t'rR.
A factor to be cons'idered ìn the interpretaticn of the effects of
cocaine is the effect already d'iscussed cf increasìng flow rate on
metabolite efflux in segments inculrated w'ith INT NA. The latter
finding ìndicated that at the higher flov¡ rate (2.0 ml.min-l), the flux
of INT NA across the vessel wall was'increased and the flux of EXT NA
decreased. rlence jt is possible that the efficiency of neuronal uptake
in removing INT NA nray also be related in some way to the'intralumìnal
flow rate. Ana'lysis of the effects of neuronal uptake inhjbition at
various flow rates may resolve this question.
95.
(b) Hydrocorti sone
Hydrocort'isone exerted a potent j nhi b j tory ef f ect on 3U. ttNt,t
efflux, but did not otheruise ìnfluence the pattern of metabolite effìux
from INT and fron EXT 3H.nR. In particular, the failure of hyclrocortisone
to increar.3H.DOPEG efflux from It'tt 3u.NA suggests that the 'influence of
the corti costeroi d- sensi t'i ve C-nre'"hyl atì ng system on t.he concentratì on
which tttl 3H.NA achieves in the region of the nerve terminals was a
minor one. Sorne influence cannot be excluded since the steroid tended
to decrease the rate of 3H. OOpf g ef f I ux f rom EXT 3H. t,tA. Thi s I atter
effect may have masked the pred'icted effect of eliminat'ing a s'ite of
ìoss of NA r/ithin the med'ia, namely an increase'in 3H.UOpfg formation
from Iruf 3H.ruR. The failure of hydrocortisone to increase the flux of
EXf 3H.NA'is also puzzl'ing, since in an earl'ier study (de la Lande, 1980)
it was shown that D0CA (in the presence of cocaine) caused a two-fold
increase in flux of NA compared with vessels treated with cocaine alone.
The explanation of the difference nray be in the experimental cond'it'ions
since the latter study emp'loyed non-reserpinised arterjes incubated wjthfI
Ca" Krebs solutìon in the presence of phentolamjne (0.3rr¡1) at a flov¡
rate of 1.0 nrl .nli n- 1.
( c) Phenoxybenzami ne
Phenoxybenzamìne (PBZ) illustrated the effecis of combineci
c-receptor blockade and inh'ibit'ion of neuronal and extraneuronal uptake
on the metabolism and flux of l{4. Conrparison of the untreated (Ca++ free)
and PBZ-treated segnrents indicated that the sequent'ial processes of
uptake ( neuronal ancl extraneuronal ) tol I owed by enzymi c- i nacti vat'i on
account for B0% and 90% of the metabol'ism of II'IT and of EXT NA
respectìve'ly, and that these processes normally reduce the fluxes of
unchanged lNl and tXt 3H.NA by 84% and 58% respectìve1y. The d'iffusion
coefficients of INT anrl of fXl 3H.NA in the PBZ-treated vessels lrere not
significantly d'ifferent. The'ir value (both 0.6 x 10-6 cm2.ru.-1¡ is
96.
however, less than the value (0.8 x 10-6 cm2.sec 1¡ *.urrred in an
earlier study for EXT 3H.ttR (de 1a Lande et al, 1980). The difference
may reflect a difference 'in the experintentaì conditjons; the larger
value was derived from arteries of non-reserpinised rabbits under
cond1tions where the intraluminal perfusate (Cu** Krebs) was continuousìy
repì aced.
( 5 ) oMDA FoRI,IATI 0Ñ
in segments incubated with Ca++-free and Ca++ media there was
considerable variability in est'imates of the 0MDA contents of the
solution conta'inìng the substrate (3H.run). Th'is variabìlity was not
evident when prazos'in vras present and for th'is reason the discussion of
the influence of the surface of entry of NA on its conversion to
Q-methylated-deaminated metabol'ites will be restricted to prazosìn-
treated preparations. Aìthough the composition of the 0MDA fractjon
was not analysed, its h'igh medium to tissue ratio (5"0) suggests that,
under the expenimental condit'ions emp'loyed, the major proportion of the
Oii4DA fraction is lvlOPEG. When normal segments of artery are incubated-Lfin Ca-"'Krebs solution (Head,7976) the medjum to tissue ratios of
MOPEG and VMA are .l0.3 and 0.8 respectively; thìs suggests that in the
present study I'10PEG predominates in the OltlDA fraction. There was I ittle
difference between the relative effluxes of 0t4DA ìnto the INT and EXT
solutions, nor was there any effect of hydrocortisone on these effluxes.
However, 'it has been pointed out by Fíebig and Trendelenburg (1978b), that
corticosteroid-sensitivity does not prec'lude the possìbiì ity that DOPEG'
after its efflux from the sympathetic nerves, ffiây be O-nlethylated in the
corticosteroid-sensitive extraneuronal compartment, since its high
lipophiììcity (Mack and Bön'isch, 1979) would enable it to diffuse directly
97.
across the cell membrane and thus by-pass the steroid-sensitive extra-
neuronal uptake system which transports NA 'into the effector cell
(considered 'in greater deta'iì in Chapter 6). The present results
Suggest that this mechan'ism also operates in the rabb'it ear artery.
The ev'idence is that the efflux of OMDA was inh'ib'ited more strongly by
cocaine ìn vessels incubated wìth EXT 3H.ttR (by 35%). Furthermore, the
efflux of OMDA from the advent'it'ial surface was more sensitive to
cocaine than efflux from the intimal surface. Such a selective effect
suggests that cocaine-sensitive OMDA formation was localised in the
outer regions of the vessel wall, ì.e., those regions where, due to'itS
origins in sympathetic nerves, the concentration of DOPEG was greatest.
By the same argument the relative insensjtivity of OMDA efflux from the
int'imal surface to coca'ine implies that a second pathway, which is
'insensitive to coca'ine, predom'inates 'in the 'inner region of the wall.
In v'iew of the low concentratjon of D0PEG ìn the inner regions of the
vessel wall ('i .e., near the 'intima) it is suggested that th'is second
mechanìsm ìs not dependent on DOPEG wh'ich effluxes from sympathetìc
nerves. The cocaìne-insensitive pathvlay of OMDA formation, a'lthough
'insensitive to hydrocortisone, appears to be sens'itìve to PBZ. Th'is
possiUìtity was suggested by the 62% clecrease 'in OMDA efflux produced by
PBZ treatment in segments incubat,ed vrith INT 3tt.i'lR. These segments,
like those treated wìth prazosin, did not constrict in response to 3H.NA
because PBZ also blocked the post-synaptic s-receptors.
In view of the above resuìts, it ìs suggested that coca'ine-'insensitive
QMDA formatìon occurs in an extraneuronal compartment into wh'ich NA ìs
transported by a cortìcostero'id-insensitìve, but PBZ-sens'itìve, transport
process. Although these results provide no indication of the morpho'lcg'ìcaì
98.
site of such a compartment, there'is evidence in the rabbit aorta that
QMDA is formed in non-neuronal structures in the adventitia by a process
which is insensitive to both cocaine and corticosteroids (Schrold and
Nedergaard, 1981); whether this process is PBZ-sensitive has not been
reported.
(6) SUMMARY
In summary, the results of this chapter show that the surface of
entry of NA exerts a profound effect on its ntetatlo'lism; inactivation by
the neuronal dearninat'ing pathway predom'inating when NA enters vìa the
adventit'ia, and extraneuronal O-methylating pathway when NA enters via
the 'intjma.' Intraneuronal deamination of NA occurs only after its
transport'into the nerve by the coca'ine-sensitive uptake process, and
Q-methylatìon of I'lA occurs only after its transport into an extraneuronal
compartment (presumably'bhe smooth muscle cells) by a corticostero'id-
sens'itive uptake process. The O-methylated-deaminated metabolites
appear to be forned in part by 0-methylating DOPEG releasedfrom nerve
terminals and in part by a pure'ly extraneuronal rnechanism which, although
corticosteroid-insensit'ive, is sens'itive to PBZ (considered in more
detail in Chapter 6).
The different rates of deaminated metaboiìte formation from INT
and from EXT NA, and the different pattern of effluxes of Nl'lN from the
two surfaces can be explained in tetms of a gradient of concentration
of NA between its surface of entry, and the opposite surface. The
greater efflux of the deanrinated metabolites from the adventitiai
than from the int'inlal surface appears to be ìndependent of the gradìent
of concentration of NA but is consistent v¡ith evidence of regional
differences in djffusivìty of NA, and presunrably its metabolites.
99.
Based on the dÍfferent rates of DOPEG formation from INT and from
EXT NA, it is suggested that. the decrease in concentration of INT NA
between the intinra and the nerve terminals is greater in constricted
than in relaxed vessels. A possible explanation is that constriction
may decrease the diffusivity of NA within the vessel wall; this
expìanatìon is supported by the association of constriction with a
decreased efflux of Nl'll'l from the vessel wall.
CHAPTER 5
DIFFUSION AND METABt]LISI',I OF
H.ISO iN PERFUSED ARTERY SIGMENTS3
100.
CHAPTER 5.
DI FFUSI ON AND METAI]OLISI,I OF 3H. ISO IN
PERFUSED ARTERY SEGI'1ENTS
I NTRODUCTION
In the preceding chapter the influence of the surface of entry o'f
NA on'its O-nrethylatìon to NMN in reserpìnised rabb'it ear arteries was
examined. S'ince, conceivably, the format'ion of Nt4t'l rnay have been
influenced jn some way by the associated conversion of NA to O-methylated-
deami nated metabol i tes , i t was des'irabl e to exam'ine the patterns of
efflux of tlfe O-methylated derivat'ive of isoprenaìine (IS0) in vessels
ìncubated with tj)3H.IS0. The tow affinìty of IS0 for neuronal uptake
and high affinìty for extraneuronal uptake was described by Iversen
( 1967) . Furthernrore, i t f orms onìy one metabol i te, name'ly 3-methoxy-
isoprenal i ne (t,leOISO) by the act'ivi ty of extraneuronal C0t'1T but ì t is
not deamì nated by ft1A0 (Hertt j ng, 1964 ) . The ki neti cs of 0-methyl ati on
of IS0 in the rabi¡it ear artery was defìned by Head et al (1980), who
showed that the 0-methylation occurred in a single corticosteroid-
sensitive extraneuronal compartment (Kr- = 2.7¡tl4).
In the present st.udy, the d'istribut'ion of 3H.l4e0lS0 betweerr the
solutions bathjng the INT and the EXT surfaces of perfused segments
of rabb'it ear arteries incubated with 1+¡3n.IS0'is descrjbed.
METHODS
The experirnental technique was jclentical to that used in Chapter'4
and described in the General t{ethods (Chapter 2). Brief'ly, ear arteries
fronr reserpinised rabbìts were perfused with either INT (1)3H.lSO
(0.18uM) or bathed in EXT {1)3H.IS0 (0.1Buir',l) in ca++ free Krebs solution.
Cocaine (29uM) was present throughout these studies t.o exclude any ìnvolve-
nrent of neuronal inactivation.
ì0r.
Table 5.1lq
The flux of unchanged (t)3H.ISo and efflux of SH.MeorSo into the soluti.onsbathing either surface of perfused rabbit ear artery segments when (t)5H.ISO(O.l-B pM) is applied to either the intimal or the adventitiaL surface.Values are means t Snu.* indicates significance (p<O.05); unpaired t-test.
o
Incubatingsolution
Treatment(n)
MeOISO effh¡xnmol .g-1 .go*irr-l
INT EXT
ISODiffusion
Coefficientxlo-7cm2.min-1
ISOFh;x TotaI
o.59to. tt
L.1-7t0.11
L.3110.13
o.51to. 06
1.85t0. t-6
o.2910.03
o.1-3lo.o2
o.12to. 04
2,OL+o.43
3.97+o.47
INT SH.ISO Untreated(n=5 )
Hydrocortisone(n=5 )
5.32t1 .03
*
1 .8510.55
Untreated(n=5 )
Hydrocortisone(n=5 )
*
25L2
1+0
o.47to.05
99L4
0+O
o.52to .04
1 .51_to.l-B
o.r4lo.o2
o.28lo.o7
*
o.42to. og
Exr 3tr. tso
102.
1
.T.=Eoal
T-9oEc
30
10
.0
0
EXT H3H.ISO tNT (3)qi.rso
incubot¡ng solution
! coHrnot- ¡n=5)
@ avoaocoRTrsoNE ln=51
r p< 0'05
MeOlSO MeOlS0
opposite solution
Me0lS0 Me0lSC
t *
t a
0 L
Fig. 5.1
mediti¡n bathing either surface of perfused ear artery segments (fromrabbits which were not reserpine pretreated) where (l)3n.ISo(O.l-8 uM)is applied either to the adventitia (EXf) or to the intima (INT).Note that cocaine is present throughout these studies to elirninateany neuronal. involvement.* indicates significance (p<0.05); unpaired t-test.
The effect of hydrocortisone (4L3 uM) on the effh¡x ofSH.metaborites in nmol.g-1.3omin-1 into the ca++ free
103.
In al'l experiments a second incubation \¡Jas carried out on each vessel
after a 60 rninute washout period wh'ich included a 30 m1nute pre-ìncubatjon
with hydrocort'isone (413u1,1). The 3rl.IS0 *u, then appl'ied to the same
surface of the artery as in the first'incubation in the presence of
hydrocort'isone. The anlount of unchanged 3H.lS0 which fluxed through
the vessel wall, and the anlount of 3il.l4e0IS0 which effluxed into the
two bathing so'lutions wgre then assayed by the modified cascade column
chromatographìc rnethod described in the General tlethods (F'ig. 2.4).
The recoveries and crossovers are shown in Table ?.3.
RESULTS
The rel ati ve ef f I uxes of 3H.lvleOlS0 f rorn the two surf aces durì ng
incubation with INT or with EXT 3H.tSO (0.lBuM) are shown in Table 5.1 and
also in Fig. 5.1. The major feature is that a greater proportìon of
the netabolite (3H.NeOtSO) effluxed into the solution containing the
substrate. These proport'ions are 2.6 and 1.9 ìn vessels incubateC
with INT and rvith EXT 3H.tSO respectìveìy. The toial efflux'of 3rt.l,le0lS0
fror¡ vessels incubated with lttt 3H.lS0 vras greater than that from vessels
incubated with EXT 3tt.IsO (vaìues of 1.85 and 1.51 nmol.g-1.S0 min-1
respectìvely), hourever this d'ifference was not statisticalìy signìficant
at the 5% level.
The effect of hydrocortisone (413utq) treatment uras to t"educe
3H.l',t.OtsO fornatiori by 77% and 7?% when 3H.tsO entered via the INT
and EXT surfaces respectiveìy. Further, hydrocortisone-treatment was
associated with an ìncrease in both the flux and the'diffusivjty (as
estinlated by the apparent diffusion coefficient) of 3H.IS0 by 2.0 and
2. B f ol d for I l,lT and EXI 3tt . i S0 res pecti vely .
104.
DISCUSS I OI-I
The total effluxes of 3H.MeOIS0 from segments incubated with Il'{T
or with EXT 3H.tSO are approximateìy 2.0 and 1.5 fold greater,
respectively, than those of 3H.Ulqru from vessels incubated witfr 3U.ruR
under s'imilar cond'itions (i.e., in the case of 3H.ttR incubatjons, where
the vessel was treated with prazosin to ensure relaxation and with
cocaine to inhibit neuronal uptake). The inhjbitory effects of
hydrocortisone on these effluxes are in accord with earlier results
with non-perfused segments (Head et al,1980) which'indicated that the
major proportion of 3H.iq.OlS0 u¿as derived from a corticosteroid-sensi t'ive
extraneuronal uptake and 0-methylating compartment. The present result
suggests, furtherr¡ore, that the 3H.MeOlS0 was derjved from the same
compartment, irrespective of the surface of entry of 3H.ISO into the
vessel wal I .
In vielv of earlier evidence from artery strips lhat approx'imateìy
80% of the MeOlSO wh'ich was formed escaped'into the bathjng solution
during incubat'ion witn 3n.tSO (Head et al, 1980), the dÍfference between
the total effluxes of 3H.MeOIS0 and 3H.Nt"lN implìes a correspond'ing
difference between the rates of O-nrethy'latìon of the two amines by the
vessel.
The difference'is in accord with the reported hìgher affinity of
the steroid-sensitive extraneuronal uptake systetn for IS0 than for NA.
A contrìbutory factor may be the convers'ion of NA to other O-rnethylated
de¡ivatives (tfre OI1UR fraction) besides I'll,ll'1. If so this conversion
appears to be more intportant when the parent anljne enters via the
adventitial surface. Under these latter conditions the total efflux
of 3n.NMN plus 3H.ONOR (7.25 nmol .g-1 u, shown 'in Tabl e 4.2) was close
105.
to that of 3rl.l4e0lS0 (1.51 nmol .g-1). However, rvhen the amine entered
via the intimal surface the efflux of 3H.Htttt plus 3H.OMDA rvas only tvro-
thirds that of 3tt.NuOIsO (i.e. , I.2I nmol .g-1 .o*pured w'ith 1.85 nmoì.9-1
res pecti vely )
The distribution of MeOISO efflux between the intimal and adventitìal
surfaces was qualitatively ident'ical with that of Nl,ll'l (tne latter, both
in the case of untreated and cocaine-treated segments) in that, l'ike
NMN, I'leOiS0 effluxed preferentialìy frorn the surface of entry of the
parent amine. The ratio of the effluxes fror¡ the two surfaces was
somewhat higher in the case of It4e0IS0 (2.6 and 1.9 for INT and EXT
?"H.IS0 respectively, compared with ratios of NMN in cocaine-treated
vessels of 1.7 and 1.6 for INT and EXt 3H.l'lA respectively). Neverbheìess,
these ratios are still close to the theoretical rat'io of 2"0 predicted
on the basis of the assumptions already discussed in Chapter 4, and
whose theoretical derivation is presented in Appendix 1.
In thìs respect, the data adds weight to the argument that the
concentration of the parent amine when appììed to either surface
declines un'ifornrly across the media. It is of particular interest that
the ratio of effluxes of 3H.N.0IS0 from the two surfaces tended to be
greater for INT than fXt 3il.IS0 since such a tendency is a predictable
consequence of the presence of an adventìt'ia vrhich is deficient in
sites of 0-rnethylation compared with the nted'ia.
Subsequent to this study, Branco et al (1981a) have reported that,,
per unit rnass, the isolated media of the rabbit aorta possesses about
twice the 0-nlethyìating activity (us'ing 3tt.tSO,2pl,1, as the substrate) than
the i sol ated advent'i ti a. A1 though thei r resul is sugges t that the
isolated adventitia does possess signifjcant iS0 0-nrethylating activity,
106.
Their ratio of activìty to that in the rnedia js not very meanìnEfu1 as
the process of separating the ned'ia and adventìtia, as these authors
c.ì early i nd'icate , marked'ly decreased (by 60%) the O-methyl ati ng capaci ty
of the intact aorta (when compared r¡r'ith the O-methylating capacity of
the isolated media). If t.he darnaging effect of the separation process
was largely upon the O-methyìating system 'in the media, then the two-
fold rat'ios of C0i'1T activities in the separated regions would greatly
overes ti nlate the quant'i tati ve i mportance of adventi t'i al 0-methyl ati on .
Two other features of their study are relevant to the present
resu'lt-s. Firstly, the 0-methylating act'ivity in the isolated adventitia
in the rabbit aorta d'iffered from that'in the isolated media by being
much less sensit'ive to inh'ib'ition of C0l4T (Oy UOSZT) and inhibition of
extraneuronal uptake (by cortexone). Hence ìt might be argued that
the small residual MeOISO formation persìsting in the presence of
hydrocortisone in the rabbit ear artery represents O-methylation of IS0
'in the adventitia. However, this possibil ity seems unlikely as the
hydrocortisone-insensitive MeOIS0 efflux from the adventitial surface
did not differ s'ignificantly from that fr^orn the medial surface (fig. 5.1).
In the case of I'llnlN, the hydrocortisone-resistant ef fl ux represented only
8% and 7I% of the total efflux from It'lT and from EXT NA respectively.
These observat'ions do not exclude, but render less likely, the possiblìity
that the adventitia contributed to the 0-methylating capacity of the ear
artery to the extent vlh'ich the relative data of Branco et al on the
rates of 0-methyìation in the 'isolated adventìtia and isolated media
of the rabb'it aorta mì ght suggest.
The second feature of their data is that, usìng autoradiographic
techniques, they showed that the smooth muscle cells of the nedia
represented almost exclusìve1y the s'ites of corti costero'id-sensi t'ive
107.
accumulation of 3tt.IS0. In this respect, their data adds further support
to the assumption (Chapter 4) that the sites of O-methylat'ion are
uniformly distributed across the medìa.
In summary, the pattern of efflux of 3tl.N.0IS0 from the two
surfaces of the rabbit ear artery resembles that of 3H.NMN both
quantitatively and qualitatively. It seems unlikely therefore, that
this pattern (in the case of 3H.tlþ1ru) was greatly influenced by the
associated conversion of 3H.NA to other 0-methy'lated metabolites
CHAPTER 6
METABOLISM OF (-)3H.DOPEG IN
ISOLATED ARTERY STRIPS
108.
CHAPTER 6.
METABOLTSM 0F (-)3H.OOpre IN ISOLATED ARTERY STRIPS
I NTRODUCT I ON
As explained in Chapter 4, the O-rnethylated-deaminated metabolites
of NA can be,'in theory, formed by the 0-methyìat'ion of the deam'inated
metabol jtes $PEG, and D0l'44, after the latter have effluxed from the
sympathetic nerves. Hovlever, direct evidence that these metabolites can
in fact be Q-methyìated ìn a peripheral organ, with cell structure
intact, is lacking. Evidence for such a mechan'ism has been sought jn
the present'study by incubatìng artery strìps wìth 3H labelled DOPEG,
and analysìng the jncubating medium and tissue for unchanged DOPEG
and its g-methylated derivative. The study was restricted-to DOPEG
for tu¡o reasons. F'irstly, since'it js formed at a much hìgher rate
than D0l4A, it seemed likeìy that 0-rnethylat'ion of IJ()PEG would represent
a more 'important pathway of OMDA formation than 0-nlethylation of DOi'lA;
and secondly, as poìnted out by l4ack and BÖnisch (i979)' DOPEG .is much
more lipophil'ic than DOl"lA and hence a mechanism of 0-methylat'ion
involving direct diffusion of the deaminated metabol'ite into a COMT
containing cornpartnlent is much more like'ly to apply to DOPEG than to
DOMA.
Another reason for study'ing O-methyìation of DOPEG was purely
techni cal . Neì ther 3tt . OOpf e ol^ 3H
. DOMA are commerci al ]y avai I abl e.
As reported in this Chapter,3H.DOPEG rvas prepared by incubating rat vas
deferens wi th (- )3H.1{4, and puri fy'ing the appropriate chromatographì c
f ract'ion . The hi gh yi el d of 3H. OOpf e , pì us the I ow crossover of 3tl.
tttR
')
into the "ll"OOPEG fraction (0.A3%) made thjs procedure technicaììy
feasibìe, but posed sorne clifficulties in the case of 3H.ooNR
109.
3where the yield is much lower, and where the crossover of
considerabìy higher (2.5%).
H.NA is
METHODS
Preparatìon of 3H.oOPre.
(a) The princ'ipa1 of the method was that a readi'ly available tissue
(the rat vas deferens), known to possess a high rate of 3H.DOPEG formatjon
(Graefe et al , !g73), was incubated with (-)3H.NA and themetabolites
fractionated by the colunrn chromatographic nrethod descrìbed in the
General Methods (Chapter 2). The 3H.D0PEG vras isolated 'in the relevant
fraction (fraction 3) as descrjbed below
(b) Four rat vas deferens (250nrg) were incubated in 4nrl of ascort¡ic
Krebs sol uti on contai n'i ng (- )3H . NA (1 . Zulvl) for 60 mi nutes at 37oC and
bubbled rvi th 95% 02, 5% C)Z. At the end of th'is perìod, the incubatìng
medi um was aci di f i ed (0. 4m1 of 0 . 11',l HCI and 0. 04m.ì 0. 6M as corbi c aci d )
anci f racti onated by 'uhe cas cade col unrn chrornatographi c nlethod . The
only m'inor modification was that the Zml of 0.2t4 aceùic ac'id effluent
(contain'ing most of the 3H.DOPEG) was not furthen d'iluted with the usual
2m1 of water. The 3H in thi, 3ti.OOp¡e fraction (termed A) was then
measured to determ'ine the amount of 3H.DOPEG formed. A typìcaì exper'ìnlental
yielcl was approximately 0.6 nmol of 3H.DOPEG. This r¡ras suffic'ient for
approximateìy 10 artery strip incubations when diluted with 4 parts of
unlabelled D0PEG. In exploratory experinlents th'is solution (A) was
treated in'one of three ways,
(i) the solution was subjected again to cascade column chromatography
in the normaì way; (ii ) the solut'iotl was reduced to dryness by vortex
evaporation at room temperature and the dried material redissolved in
ascorbic Krebs solution to give a f inal concentratìon of 0.18ul\'1. This
was again subiected to the normal column chrontatography; (iii) the
solution r^/as further^ purified by alur¡ina chromatography only. After
110.
adsorption onto alumina, the 3H.materiaj (i.e., 3H.DOPEG) was eluted
with 2ml of 0.11'l HCI .
The reason that ('ii) and (iii) were undertaken \'ras to devise a
method of removing the acetic acid so that artery strips could be
incubated in 3rl.DOPEG in Krebs solution. The results of (i) indicated
that when the orig'inaì fraction (A) was not further purified and
reanalyse<J by column chromatography , 76% of the total 3tt recoveretl
vlas in the'DOPEG'fraction (termed B) and 9% appeared in the'DQMA'
fraction (mean of 4 values). When the 3H.OOpfe solution (B) was
treated aga'in as i n (i ) , agai n not al I the 3l-l *u, recovered 'in the
'DSPEG' fraition, since 9% still appeared in the 'DOMA' fractjon. This
result suggested that there was a consistent crossover of 9% of the
3H. OOpf e i nto the ' D0l4A' f ract'ion, rather than that the 3H
.-DgPEG was
only 76% pure. In (ii) where the 3H.OOpEe solution (A) was vortex
evaporatecl to dryness the corresponding yield of3H in th. 'DOPEGr and
'D0MA' fractions \^/ere 34% and 38% respectrvely (mean of 5 values).
This resul t ì ndj cated that evaporatjon was associated wi th signifi cant
degradation of the 3H.DOPEG and so this procedure was abandoned. In
(iii) where the 3H.DOPEG solutjon (A) was purified on alumina a second
t'ime, 88% of the applied material was recovered in the rD0PEGr fraction
and 8% in the'D0MA|fraction. In two experiments where this material
was assayed by column chromatography ('i.e., a third adsorptjon onto
alumina), B0 and 82% of the 3H appeared in the 'DOPEG' fract'ion and a
consistent 15% in the 'DOMA' fraction. This result impfied that there
was either a persistent crossover into the'DOi',lA'fraction or son'ìe
degradation of the 3il.DOPEG during the four day period between the
origina'l preparat'ion and purifìcation of the 3U.OQpfe samp'le and
appìication orrto alunlina on the day of the experiment. But c'learly the
ìil.
Table 6.1
The accumutation and O-methylation of (-)3u.oOpEç (O.fe ul,I) in rabbit earartery strips. Val-ues shown are means t SgM.* indícates significance (p<0.05); unpaired t-test
MOPEG Formation
hmo1.g-1.somin-lTreatment n
TissueDOPEG medium tissue total
medium/tissueratio
L4
t_0
10
6
o.L2to.01
0.1010.01
o.1-o+o.01
L303
o+O
o.39+o.03
o.35lo.oz
o .31+o .01
o7o2
0t0
o.05t0. oo
0+O
ot0
0+0
0500
050l_
o200
o.36to. 01
tr
o.09to. 02
10o2
0t0.
7.4
7.O
6.2
3.5
Untreated
Cocaine
Cocaine +
hydrocort.
uo521
I 12.
0.5totql MOPEG *r p<0 001
r p<0'05t
0
0.3
0.1
0
0.2
o.2
0'1
t*
NrL Cæ CoC U05Z
HCORT
tissue DOPEG
NrL cæ coc u0521
HCORT
29 29/.13
10
.Í.çE
CJaTqoec
+
0
+
lJM
n
55
1t, 10 6
Fis. 6.1 The accumulation of 3H.DOPEG (O.fA yl{) and the formation ofits O-methylated product (3H.l¡opnC) in nmol-.g-L.3Omin-l in
rabbit ear artery strips. The dashed line indicates the tissue contentof 3H.MOPEG at the end of the incubation period. Also shown are theeffects of cocaine (29 ¡rM), of cocaine plus hydrocortisone (413 UM)and of UO521 (5s uru).* indicates significance (p <O.05); unpaired t-test.** il rr (p<O.O01); r rt
I
113.
method outlined in ('ii'i ) uras far superìor to the evaporation nlethod
in (ii) as a rneans of renloving the acetic acid and was therefore
adopted in the present studY.
Note:- In the I'ight of subsequent expeniments, the apparently hìgh
crossover of 3H.DOPEG into the'D0l1A'fraction (9%) may have been related
to the particular batch of alumìna used at the t'ime of these experìnlenis.
The crossover of unlabelled DOPEG into the 'DOMA' fraction urith this
batôh of alurn'ina was 4.5%, which was approxìrnate'ìy twice the crossover
observed r,rith other batches of alumina used in other experiments before
and aiter thìs series, and shourn in Tabl e 2.2 (Chapter 2). Further,
that the material appeari ng 'in the 'DOMA' f raction v'las probabìy D0PEG
was 'indicated by additional contparìsons using the TLC method of Heaci
et al (1976), which showed 86% of the 3H appearing at the spot correspondìng
to DOPEG which was cornparabìe with the 78% recovery quoted by Head
et al for pure unlabelled DOPEG.
RESULTS
The results, summa¡ised jn Table 6.1 and also Fig.6.1, shovl Ùhat
the artery strips O-methyìated 3H.D0PEG at a rate of 0"44+0.03 nnlol.g-i.
30 min-1. The maior proportion (85-907á) of the O-methyìated product
effluxed into ihe incubating medìum after its forrnation. The tissue
did not accumulate unchanged 3H.D0PEG to a significant extent. The
content of 3H.DOPEG remain'ing ìn the tissue at the enci of the incubat'ion
was only 0. l2+0.01 nmol .g- 1 . 30 mi n- 1; ì . e. , 67% of the i ncubati ng
concentration (0.18u1'l). This is close to th js conte.nt jf the DQPEG
in the incubating medium were d'istributed mainly into the extracellular
space, estimated by de la Lande et al (tgeO) to be 0.6ml.g-1.
ì 14.
Table 6.2
A comparison of the rate of o-methylation of SH.DOPEG witl¡ that of 3H.ISo and5H.t{¡ under identicat incubating conditions, in rabbit êar artery strips.Values shown are means t SEM.
Substrate(u til)
Treatment O-methylatedproduct.
nmor. g-1 .3omin-l n
SH.oopuc(o.r-8)
3H. rso(o.ra)
3H.ne( 0.18 )
Nit
NiI
Nil
3H.rtr"orso
Su.mopuc
3u.tr¡wIw
o.11 lO.O3
1.66 t0.15
o.51 10.04
L4
1
1
3H. ¡lt{N o.49 lO,O4 2L
5u.ng(o.re)
PrazosinCa++ freereserpine
115 .
The evidence that the product measured jn the '0MDA' fract'ion v/as
2?O-methylatecl "H.DOPtG (i.e., 'H.MOPEG) uras ìndicated by the 80%
recluction in its formation lvhen an inh'ibitor of C0l,lT (i.e., U0521, 55i,Í'i)
was also present. Holvever, this inhibition v¡as not associated with an
i ncrease i n the amount of unchanged 3H . D0PEG 'in the t'issue.
As shown ìn Fìg. 6.1, neither cocaine (29uM) or hydrocortisone
(413uM) effected 0-rnethylation, or tissue retentjon, of 3H.D0PEG to
significant degrees. The only sìgn'ificant effect was a decrease jn the
amou¡t of Q-methylated D0PEG formed in the cocaine plus hydrocortisone
treatãd vesselS compared wjth untreated vessels. However, thìs
reciucti on wás snral I (only 7B%) .
The rate of O-nlethy'latìon of 3H.OOpfe i, compared with that of
3H.¡tR and 3H.IS0 in Tabl e 6.2. The data on 3H.l{R and 3H.IS0 is taken
both from the earlìer studies in th'is thesis, and from other investìgatìor,s
(Head et al, 1980).
DISCUSSION
The potent inhibìtory effect of UCs21 on the formation of 3H.material
whi ch rvas present i n the rOMDA' f ract'ion suggests strongly that i t is an
Q-methyìated product of DOPEG formed by the acl-'ivity of CQMT. The
medium tc tissue ratio of the product (8:1) is comparable with that of
MOPEG (10:1) and very much higher than that of VllA (0.8:1). The
values for t'lOPEG and Vl'4A are from de la Lande et al (1978). Hence
there seerils ljttle doubt that the 0-methylated product ìn the present
experiments i s t'10PEG.
The relative insensit'ivjty of MQPEG formation to cocaine and
hydrocortisone ìrnplies that MOPEG forrnat'ion fronr D()PEG does not involve
neuronal uptake, or the corticosteroid-sensitive extraneuronal uptake syste-.
In this respect the results add support to the proposals of Henseling
et al(1978b) in the rabb'it aorta and Fiebig and Trendelenburg (1978b) 1n
I 16.
0 odventi t io
ooo nerves oo
med io
int imo
I umen
EXTNA
D
ooo oo0
INTNA
Fig. 6.2 A diagrammatic representation of the relative concentrationsof NA entering the artery wall either via the intima (left
hand panel) or via the adventitia (right hand panel) near the nerveterminals. This shows that the media, but not the adventitia, limitsthe penetration of NA to the nerves. The frD'r stands for DOPEG andthe arrows indicate its rate of formation; ierthe concentration ofDOPEG is greater when NA enters the wall via the adventitia sincethe access of the substrate is not impeded by the presence of themedia.
LI7 .
the rat heart, that DOPEG is capable of diffusing directly into an
extraneuronal COMT conrpartnrent and t,hus bypassing the extraneuronal
corticosteroid-sensìt'ive uptake system. However, the data does not
exclude the possibility that the extraneuronal compartment involved
in Q-methylatìng DOPEG nray be qu'ite distinct from that rvhich O-methylated
NA or IS0. Analysis of the effects of NA or IS0 on DOPEG O-methylatjon
would help to resolve this question.
It should be noted that a neuronal O-methylatìng compartment js
excluded by the evidence that C0MT activity is not present'in the
sympathetic nerves of the rabb'it ear artery (Head et a1,7975; de la
Lande et aì', 1978; Head et al, 1976).
Irrespective of the nature of the extraneuronal compartment in
which Q-methylation occurred, the data does provide the first djrect
demonstratjon that, ìn the intact tissue, D0PEG is a substrate for C0i4T.
I t therefore hel ps to expl a'i n the s ens'i ti vi ty of OMDA formati on to
cocaine when NA enters v'ia the adventit'ia (Chapter 4) s'ince the
formation of DOPEG by the tissue'is approx'imate'ly 4 fold greater urhen
NA enters via the advent'itia, than when jt enters via the intjma
(Chapter 4, Tables 4.1 & 4.2). This is shown d'iagrammaticalìy ìn
Fi g. 6.2.
The rate of O-methylation of DOPËG'is comparable with that of NA
under identical condit,ìons, and also with that of NA in the prazosìn-fI
treated (Ca"-free) reserp'inised vessels, but'is only about one quarter
that of IS0.
It is ìnteresting to specu'late whether the rate of 0-methylation
of DOPEG is sufficient to account for the cocaine-sensitive component
of OMDA formation. In preì'imìnary experinients where 3H.OOp¡e (O.iAuM)
was applied to the advent'itia of an unlreated ear artery in normal Krebs
solution, it was found that 1.14 nmol.g-1.e0 min-1 diffused jnto the
I 18.
EXTDOPE6
oo ooodventitio
nerves
EXrNA
ooomedio
int imo
DOPE6 DOPE6lu men
Fis. 6.5 Shows how an estimate was made of the concentration ofDOPEG in the region of the nerve terminals, where NA
enters via the adventitial surface of the artery. The left-hand panelshows SH.OOpgC apptied to the adventitial surface, diffusing freelythrough the adventitia, but not the media. The amount of this DOPEG
which reached the lumen in 30 minutes was used as an indication ofthe relative concentration of 3H.poPgG, formed from NA entering viathe adventitia, in the region of the nerves (as shown in the right-hand panel).
lì9.
Table 6.5 Cocaine-sensitive OMDA
The effect of cocaine (29 pM) on the efflux of O-methylated-deaminatedmetabolites j-n four different preparations, incubated with (-)3U.nA (O.18UM).Values strolvn are means t Sgl¡.*- inCicates signi.ficance (p<0.05); unpaired t-test.
fncubatingsolution
OMDA Efflt¡x nmol . g-1 .56min-1
Preparation Untreated Cocaine difference n
Perfusedsegment
fNT + EXT
EXT
INT
o.55 t0.07
o.17 lO.O5
t_.1_6 10.03
0.36 !O.05
o.37 lO.O7
o.58 10.05
0.19
o.10
0. s8
Lt, .3
11, 5
1, 4
Arterystrip INT + EXT 0.71 10.06 0.35 t0.09 o.38 2L, 7
OPË
MOPEG
120.
MOPEG DOPEG
EXTNA NA
I
Pe9m 1 odventitio
I
I
I
I
I
I
I
pegÍìo
mop€g
nI med io
þ
I
II
tMOPEG
I
tDOPEG
t lumen
NAINTNA
FiS. 6.4 This shows two possible mechanisms for the formationof I'OPEG in the artery wall. The first (suggested by the
present study) is DOPEG effluxing from the nerves entering nearbyeffector cells where it is O-methylated to MOPEG, which effluxesprimarily via the adventitia" This mechanism predomj-naies in the outerregions of the wall when the concentration of DOPEG is high (such asoccurs when NA is appl,ied to the adventítia), is sensitive to cocaine(which inhibits DOPEG formation) Uut insensitive to hydrocortisone(presumably because the highly lipid soluable DOPEG can diffusedirectly into the effector celI). The second mechanism (with l-ittLeexperimental evidence to indicate its origin) operates throughoutthe wall, is insensitive to cocaine or hydrocortisone but sensitiveto PBZ, and predominates in the inner region of the wall regardlessof the surface of application of NA.
T2I.
opposite (i.e., II'lT) solut'ion. If it is assunred that th'is flux is
directly proport'ional to the concentration in the EXT solutìon, it
can be estjmated frorn the standard diffusion equation that the flux
of D0PEG 'i nto the I NT sol uti on (0 . 5 nnrol . g- i. ¡o mi n- 1) durì ng
incubation with EXT 3tt.t'tR (0.18uM) diffused fronl a s'ite ('i .e., a narrol'r
zone in the regìon of the nerves) lvhere the mean concentration of
D0PEG *ur ffi x o.la, i.e. 0.10pM (Fig. 6.3). Assuming approxjmate
I i neari ty betureen I'10PEG f ormat'ion and DOPEG concentrat'ion, the rate
of MOPEG formation from DOPEG (0.10rM) would U. &# x 0.44, j.e.
0.24 nmo'l .g-1 gO min-1. Th'is is close to the coca'ine-sens jtive
cornponent of Ol,lDA formation fronl EXI 3rt.NA of 0.19 nmol.g-1.¡O min-1
(Tabìe 6.3). This agreement adds further support to the argument that
Q-ntethylation of DOPEG is an 'important metabolìc pathway in the
rabbit ear arterY.
As 'indicated ìn Chapter 4, there 'is a significant component of
OMDA formatjon which is insensitive to cocaine. This component appears
to represent the major pathway of formatjon when NA enters via the
i ntinra, but 'is sti I I evi dent when t'lA enters vì a the adventìtia. The
insensit'ivity to cocaine excludes the poss'ibility that'it involves
g-rnethylatìon of DOPEG after the latter is released from sympathetic
nerves. Other than its sensitivity to PBZ, the mechanism remains
unknown. Fig. 6.4 diagrantmatical ly incorporates the various pathways
of 0MDA formation (illustrated by MQPEG onìy) in relation to the
rnorphoìogy of the vessel, as suggested by the results in this chapter
and 'in Chapter 4.
CHAPTER 7
DIFFUSION OF NA ACROSS THE ARTERY WALL,
STUDiED BY THE TECHNIQUE OF OIL IMMERSJON
12?.
CHAPTER 7.
DiFFUSION OF NA ACROSS TiIE ARTERY WALL,
STUDIED BY THE TECI1NIQUE OF OIL IMMERSION
I NTRODIJ CT I ON
The study in this chapter was ìntended to assess pharmacoìogicaìly,
whether extraneuronal inact'ivatioh of l,lA, entering vìa the'intimal
surface, can influence the steepness of the gradìent of concentration
of the anri ne across the wal I of the rabb'it ear artery.
The techn'ique of oi1 immersion has been appìied to the perfused
artery in the expectation that,when the external bathing medium vras
oi1, a uniform gradient of NA would exist across the artery wali
(i.e., no concentration gradient) when the constrictor response to
the INT NA (in aqueous medium) reached steady-state. This technìque
of immersing only one surface jn oil must be distinguished frorn that
of total imtnersi'on of t'issues in oil. The latter technique uJas firstused by Kalsner and Nickerson (fg0g) to study the kinetìcs of
inactivation of biogenic am'ines in strips of rabbit aorta. The rate
of recovery of the preparation in o'il, from the previous vasoconstrictor
response appìied in aqueous medja, tvas used as a nìeasure of the rate
of removal of the amine from the receptor b'iophase by uptake, bìnding
and metabol ism.
The present technìque of exposìng only one surface to oil perrnits
the amine to be applied to one surface in aqueous med'ia while the
oppos'ite surface was L¡athed in oil and hence is analogous to the
technique of applying a silicone grease coating to one surface of
rabbit aortic stnips as used by Pascual and tsevan (1979). The reason
for restrictìng the efflux of llA into the EXT solution was to ensure a
L23.
more uniforrn concentrat'ion of the arnine in the wall and to establish
whether this was associated with a greater constrictor response. It
was reasoned that the increased response would be due primarily to
a greater recruitment of smooth muscle cells in the outer regìon of
the rned'ia, reflecting the increase in concentration in thjs region.
If the'inactivation of INT NA normally linìted penetratìon into this
region, then'inhio'ition of inactivation should augment the increase
in response to INT NA produced by the oil. In the present study, the
role of corticosteroid-sensitive extraneuronal uptake atld O-methyìation
was studied in tnìs fashion. Observat'ions have also been made on the
possible influence of neuronal uptake on the concentration of NA with'in
the med'i a.
METHODS
il) Perfusi.on systern,
Untreated rabbit ear artery segments were prepared as described
by de la Lande and Rand (1965). The principal of the method is that
artery segments vJeì^e cannulated at both ends, set up 'in organ baths
under 19 tension and bathed in normal Krebs solutìon bubbled vriLh 5%
COZ 'in 0, at -?7oC. The i ntral umi nal (INT) surface was perf used wi th a
constant fiovl penistaltic pump at 2.0 ml .rnin-1. Hence, the solution
bath'ing the extralum'inal (EXT) surface dìd not nrìx with the Il'lT perfusate.
Constrictor responses to NA applied to either surface were measured
as an incrèase ìn perfusìon pressure by a Stathanl pressure transducer
lineated tretu¡een the pump and the tissue, and recorded on Rikidenki
double channel pen recorder.
124.
EXTNA
EXTNAn
-t00
-50(L
0
tr I ll
EXTNA
ilt II
INTNA
INT NA
r0lL r
Ðff
Fig. 7 .1 A diagrammatic representation of the experimentalprotocol, showing curnulative dose-response curves
to extraluminal (eXf¡ and to intraluminal (fltf¡ NA. This wasfollowed by a further dose of INT NÀ which woulcl give a smallresponse (l-ess than 50 mmHg) which was maintained during responsesto the same concentration of EXT NA applied before and after theEXT medium was replaced with oil. Finally the small INT NA responsewas increased until a response of equal or greater magnitude thanthat to EXT NA was obtained. When all NA was washed out of the system,the EXT medium was again replaced with oil.AP : increase in perfusion pressure (mm Hg).
125.
(2) Experinrental
Cumulatjve dose-response curves were first obtained to both Il'lT
and to EXT NA. The subsequent procedures are shown diagrammatically in
Fig. 7.I. When a steady-state response to a concentration of INT NA
(chosen from tire injtìal dose-response curve so as to give a perfus'ion
pressure of 20-40 mnrHg) rvas obta'ined (Table 7.1), the NA-free EXT
sol utìon was repl aced rvi th the same sol ution (contai ni ng NA) as fvas
perfus'i ng the I NT s urface.
Table 7.1.
Concentration of INT NA requ'ired to increase
perfusion pressure (?A-40 mmllg) (means + SEM)
Treatnrent I NT NA Concentrat'i o n ( uM ) n
UNTRTATED
COCAI NE
COC + DOCA
0.28 + 0.11
0.09 + 0.01
0.05 + 0.01
9
13
Under these conditions the concentration of I'lA at either surface of
the artery vuas ident'ical. The EXT NA was washed out after the neur
steady-state response was obtained. The EXT aqueous solution was thert
replaced with paraffjn ojl (oubbled wifh 95% 0Z - 5% C0, and at 37oC).
The oil was allowed to remain until another steady-state response
was obtained. The oil was then replaced wìth fresh Krebs solution.
tnlhen the preparation had recovered, another response lvas obtained
to the EXT NA, in the same concentration as used previousìy. The tXT
NA was then repìaced wìth fresh NA-free Krebs solution. The INT NA
concentrat'ion was then progressively increased untjl a response
approxirnately equa'l to that seen during the application of EXI'NA was
5
100 EXT NARESP.\Ð- ->-
126.
INT NA
estimqted INT NAco nc entrqt ion
cñ-E
5l¡l.J)zofLtt)lrlE
EXT OIÊRESP.
--->;- I
I
I
I
I
úI
I
I
I
I
I
I
I
vI
I
I
50
010-8
CONC. NA IMI16
Fig. 7.2 This shows the dose-response curve to intraluminal (INT)NA (solid line). The dashed lines indicate how the
concentration of INT NA required to produce the same response urasestimated either where the same concentration of NA was added to theadventitial surface, or where the EXT aqueous medium was replaced withparaffin oil, both during steady-state responses to INT NA.
127 .
obta'ined. This protocol was repeated in the presence of cocaine (29pt4)
and cocajne plus DOCA (13uM). In most experìments the effect of
EXT oil alone (i.e., wìthout NA) was examined to test the possìbility that
paraffin oil may have intrinsic pharmacolog'ical action-
The increases ìn sensitivity produced by the EXT NA, and the oil.'were
expressecl in ternls of the increases in concentrat'ion of INT NA producing
'bhe -same responses as ixT NA, and o'il ' (Fìs' 7 '2) ' -Tiris assu;rres-that
the dose-response curve to EXT NA, and to EXT oi1, parallel those to iNT NA-
RES ULTS
In five untreated arterìes, the addition of EXT NA during the steady-
state response to IfiT NA produced a further constriction wh'ich was sustainec
during the period of appì'ication (2-3 minutes). This response was equival¿'nr-
to an increase in sens'itiv'ity to INT NA of 1.8 fold (Tabl e 7.2). Repìacìng
the IXT aqueous med'ium wjth oi1 produced a much smaller increment in the
response than did EXT NA; the'increased response vJas not sustajned over a
3-5 minute period'in 4 of the 5 vessels exam'ined. Based on the peak of
the transient response only, the o'il increased the sensitiv'ity to INT NA
by a f actor of approxi mately 1 . 4. The theoretÍ cal s'i gn'if i cance of the
latter estimate is dubious since it is not based on comparisons of steady
state responses; nevertheless it does shov¡ that even at its max'imum, the
resporrse to oil was small compared with that to EXT NA'
Table 7.2.
Potentiation of Il'lT NA response by EXT treatrnent with ejther
the same concentration of NA or paraffin oii. (Geome,i.ric means + SEi'1)"
Treatment EXT NA EXT OIL 11
UNTREATED
COCAI NE
cOc + DOCA
1.84 + 0.26
3.44 + 0.31
2.38 + 0.26
1.44 + 0.11
1.46 + 0.16
1.68 + 0.i7
5
9
* values b/ere estimated as shown in Fig. 7 .2.
13
128.
ExÎ trA ml ãT Ct EXl lållol
-
En ot
-
oI¿gl¡lGetãt¡¡
E
f0 13¡ ngrnI tltrm¡n
FiS. 7.3 This shows a typical trace with the effects of EXT oiland of EXT NA on the responses of the perfused rabbit ear
artery to INT NA. Arrows indicate the periods of application of INT NA.
i¡A15
r29.
In 9 cocaine (29ui'l) treated arteries the effects of EXT NA, anc!
of EXT ojl, lvere qualitatìve1y sinrilar to their effects in untreated
vessels. Thus, in contrast to the sustained response to EXT NA in
each of the preparations, only one of the vessels showed a Susta'ined
response to ojl. In the cocaine-treated vesse'ls, the equìvalent increase
in sensitivity to EXT NA was 3.4-fold; i.e., approximate'ly doub'le
that seen in the untreated preparation. As in the case of the untreated
vessel , the effect of EXT oil, based on the in'itial peak response only,
was equ'ivalent to an ìncrease of 1.5 fold to INT NA. Hence, cocaine
treatment augmented the effect of EXT NA, but did not lead to a more
pronounced response to the o'il.
In contrast, in the presence of DOCA and cocai¡e (F'ig. 7.3) the
response to oil was well sustained in 13 of the 16 segments examined.
Kinetica'l'ly, the response to EXT NA and to EXT oil during the steady-
state response to INT NA d'iffered nrar"kedly. The response to EXT I'lA
achieved steady-state rapidly (withìn 30 seconds), whereas the response
to oil was slower in onset, taking 3-4 minutes to plateau. Quantitatíveìy,
the increase in sensit'iv'ity produced by EXT oil was on average only 70Îá
of that produced bY EXl' I'lA.
DI SCUSS I ()N
The observat'ion that, during the response to INT NA, the cocaìne-
treated rabbit ear artery constricted further v¡hen NA was applied to the
EXT surface confjrms the earlier findìng of Kalsner (1972). The
simplest expìanatjon is that proposed by Kalsner, nameìy, that the
concentrat'ion vrhich INT NA achieves'in the outer region of the smooth
muscle 'is less than 'Lhat in the inner regìon, i.ê., close to the surface
of appl'icat'ion of I'lA. The fact that the effect of EXT NA was greater
i30.
'in the presence than in the absence of cocaine suggests that neuronal
uptake may have been one of the factors responsible for the lower
concentration of iNT NA in the outer region of the medìa. However, a
more I i kely expl a.nat'ion i s that cocai ne, by 'i nhi bi ti ng neuronal
uptake, perm'itted EXT NA to achieve a hìgher concentration in the
underlyìng (i.e., outer)region of the media. In the presence of
cocaine and DOCA, the effect of EXT I'lA was not further augmented, but
tended to be less than when cocaine alone was present. Although the
concentration of DOCA used (13u1'1) was less than that previously shov¡n
to cause profound'inhibition of extraneuronal uptake (Johnson and de la
Lancie,l978), it was nevertheless the concentration which produced
near maxinrum potentiat'ion of the responses to catecholamines in the
study of Johnson and de la Lande (1978). Enhanceci sens'itivìty to
INT NA (approxinrately 2-fo1d) was also apparent'in the present study
when the concentration of INT NA which produced equ'ivalent constriction
in cocaine alone, and cocaine pìus DOCA preparations are compared
(Table 7.1). Hence the failure of DOCA to further augrnent the effect
of EXT NA l¡hen the latter v¡as added durÍng the response to INT NA
imp'li es that extraneuronal uptake i n the nledia vras probabìy not the
major factor responsible for the decreasìng concentration of INT NA
in the outer media. However, this conclusion does not take into
account the effects of oi I .
0il was used to prevent NA from escaping from the adventitìal
surface. Under conditions where NA is not inactivaied in the vessel
wa'll, and NA cannot escape from the adventitìa, INT NA should attain
the same concentration throughout the artery rval I .
l3r .
INT
NA
INTNA
INTNA
II
ERVEN s
KREBS
0tL
EXT
NA
_MEOI \/o
Fíg. 7.1 A diagrammatic representation showing the effect ofextraneuronal uptake in the media on the gradient of
concentration of rNT NA when extraneuronar uptake is active (solidline) and when it is blocked by DOCA (1S Um) (dashed tine). The toppanel shows normal Krebs solution bathing the adventitia, the middtepanel shows the EXT agueous medium replaced wi-th paraffin oil and thelower panel where the same concentration of NA is applied to theadventitia.
r32.
The reler/ant finding here is that an augmented steady-state
response to INT NA was produced by oìl onìy when DOCA was present.
This is precisely what would be expected if extraneuronal uptake was
a significant factor which prevented INT NA from achiev'ing a uniform
concentration throughout the wal I .
Hence, the conclusions drawn from the effects of EXT NA, and of
oil, on sensitìvity to INT NA appear to be at variance lvjth each other;
the former effects imp'ly'ing that extratreuronal uptake does not
contribt¡te to the decline in concentratìon of INT NA as'it diffuses
across the wall, vlhile the effects of oi'l 'imply that extraneuronal
uptake does'have a major influence. A partia'l explanation is illustrateci
diagrammatjcal'ly'in Fìg. 7.4. It shows that in theory, the ìnfluence
of extraneuronal uptake on the concentration of I'lA with'in the nted'ia
(treated as a plane sheet) wìll be tlvice as great when NA enters
from one surface under conditions where it cannot escape from the
oppos'ite surface, than when NA enters from both surfaces sjmultaneously"
This factor may contribute to the different effecis of DOCA on the
sensi t'ivi ty i ncreases produced by EXT l{A and o'il .
Qther evidence rvh'ich suggests that the effects of oil reflect a
role of extraneuronal uptake stems frorn the kinetìcs 01" the response.
In the DOCA treated preparation, the response to oil was characterjseci
by a slow onset (tÞ,. = 2-3 m'in. ) and a rapid offset (Fig. 7.3). The
slower onset accords v¡ith the time required for the INT NA to diffuse
throughout the outer regìons of the muscle rnass; the fast offset tinle
is exp'la'ined by the fact that once the oil is rep'laced by Krebs, the
NA in the outer reg'ion can now diffuse freeìy from the nearby advent'itial
surface. Prest¡mably the more rap'id onset cf t.he response to EXT NA is
133.
because the amine has onìy to transverse the adventitìa, in which jt
is freeìy diffusible, to reach the outer smooth muscle ìayers of the
medi a.
If the above arguments are accepted, then the relativeìy smaì'ler
effect of oil, than of EXT NA, on the sensjtìv'ity to INT NA can be
exp'laineci in one of two ways; either that extraneuronal uptake r,vas
not compìeteìy blocked by DOCA, or that there are cther NA'!nactjvating
processes in the media which are not sensjt'ive to DOCA. The latter
possibiì'ity is supported by the ev'idence in Chapter 4, where it was
shown that the formation of O-methylated-deaminated metabolìtes of llA
túere 'insensit'ive to another corticosteroid (hydrocortisone) and
that this lack of sensitivity vras particularly evident when NA ente'red
via the intinlal surface.
There remain a nunrber of puzzling features of the data for t^rhich
there is not an obvious explanatìon. The main one is (as previously
indicated) tne tendency for the effects of EXT NA to be less in the
presence of cocaine pìus DOCA than in the presence of cocaine alone.
CHAPTTR B
UPTAKE AND METABOLISI,.I OF CATECHOLAMINES
IN THE NORMOTENSiVI AND DOCA-SALT
HYPTRTENSIVE P.AT TAIL ARTERY AND
LEFT ATRIUI\l
134.
CHAPTER 8
UPTAKE AND METABOLISM OF CATECHOLAMINES
IN THE NORMOTENSIVE AND DOCA-SALT HYPERTENSIVE
RAT TAIL ARTERY AND LEFT ATRIUM
I NTRODUCT I ON
Ear'ly i nves t'i gat'ions i n the author's I aboratory were ori gi naì 1y aimed
at examinìng the'inactivation of NA both in normotensive and hypertensive
rabbit ear arteries. However, considerable difficuìty was experienced in
the developing of a reproducible hypertensive model in rabbits vrithout
excessive wastage of anìmals (Johnson, 1975). For thjs reason the rat
was chosen ínstead since hypertension can be readily ìnduced by a variety
of techniques. The model chosen was that of DOCA-salt treatment in the
nephrectomised rat since it offered an opportunity to assess, not onl.y
the relationship between inactivation of NA and hypertension, but also the
effects of chronic treatment with an inhibitor of extraneuronal uptake.
Pharmacological and bÍochemical evidence that DOCA inhibited extraneuronal
uptake in the rabbit ear artery b,as presented by Head et al (tgzs). The
possibiìity that the inhibitory action of DOCA on extraneuronal uptake
might contribute to the hypertensive response in D0CA-salt treated rats
does not appear to have been previously examined. The only relevant
evidence which could be found in the extensive literature on this model
was in the study of de Champlain in 1967. His data indicated that the
isolated hearts of DOCA-salt hypertens jve rats, ',vhen perfused with. _? I(1)"H.NA, did not retain as much "H.NMN (a product of extraneuronal CgMT
u.arutar) as dicl the hearts of the normotensive controls.
135.
The main vessel selected for the present study was the rat tail
artery. This was shown by Hodge and Robinson (1972) to possess a dense
sympathetic innervation whjch was confined to the border of the media anC
the adventitia (as in the rabbit ear artery). Sjnce the rat tqil artery
is a smalìer, thinner walled vessel than the rabbit ear artery, it'istechnicalìy more difficult to cannulate and perfuse. However, Venning
and de la Lande (1981) demonstrated that it was possible to examine this
vessel pharmacologica'lly in a simiìar way to the rabbit ear artery described
by de la Lande and Rand (1965). The former workers showed that the rat
tail artery cìoseìy resembles the rabbit ear artery with respect to jts
sens i ti vi ty to i ntral umi nal ly and extral umi nal 'ly appl i ed catechol ami nes
and the relative influences of neuronal uptake on these sensitivities.
Furthermore, these workers showed that the vessels from the hypertensive
rats were 3-5 fold more sensitive to NA than vessels from normotensive
controls. Their results, together with those of Wyse (1976), using the
technique of oiì immersíon, had indicated that the neuronal uptake had
exerted a rnuch greater influence on the pharmacologica'l response to NA
than did extraneuronal uptake. However, the metabofic pathways of NA
inactivation had not been examined by the more djrect procedure of
measuring the accumulation of unchanged amine and the formation of the
metabolites when the tissue was incubated witn 3n.¡¡R.
The experimental investigation in this chapter has, as its prÍmary
aim, the ana'lysis of the metabolism of catecholamines in the rat tailartery. l^lherever pract'ical , comparative studies were carried cut on tailarteries from DOCA-salt hypertensive rats at a time of treatment when
hypertension r^ras well developed, i.e., after three weeks of treatment
(unìess specified otherwise in the text)
136.
As mentioned in the General Introduction (Chapter 1) it was hoped
to extend this study to an analysis of the metabolism in perfused segments
of tail arteries at various stages of the development of hypertension.
However, since many of the studies in the perfused rabbit ear artery had to
be repeated, due to the supply of "false'ly labelled" (-)3H.NA, jndicated jn
the report of Starke et al (1980), time did not allow this phase of the
study to be undertaken. Hence the present study refers only to the
metabolism of NA, and of IS0, in non-perfused segments of the rat tail
artery.
In view of the evidence of de Champlain et al (196i), described above,
comparisons were also made with heart tissue (tfre isolated left atrium
was chosen) of hypertensive and normotensive rats.
METHODS
(1) Incubation studies.
Incubation studies were carried-out as described in the General
Methods. The prìnc'ipaì of the method was as follows.
Rats were killed by a blow on the head and bleeding. T'issues were
rapidly rernoved and pìaced in vials containing normal Krebs solution and
bubbled with 95% 0, and 5% COZ at 370C. Test drugs were added 30 minutes
prior to incubation with (-)3H.NA or (J)3H.IS0 for a further 30 minutes.
At the end of the incubation tissues were washed for 5 seconds in 2ml of3H-fr.. Krebs and extracted overnight in 0.4M HCI0O (contain'ing 3mM EDTA
and 10mM NarSO.) at 4oC. The incubation medium vras acidified with 0.2m1
of 0.1M HCI and 0.02m1 of 0.6M ascorb'ic acid immedíate'ly after the tissue
had been removed at the end of the incubation period, and stored at OoC
before being assayed. The 3H content of 0.lm1 aìiquots of each of the
acidified incubatjng medìum and t'issue acid extract was determined before
fractionating the unchanged 3H.t'tR and 3H metabolites by the cascade coiumn
137.
chromatographic method as described in the General Methods (Chapter 2).
In studies using 3H.IS0, the incubation procedure was identica'l; however,
the column separatjon was abbreviated, as described in the General Methods,
since on'ly one metabol'ite separation was required (3H.NuOIS0 appearing in
fraction 2). In some early experiments 3H.lS0 and 3H.M.OIS0 *ur.
separated by the TLC method of Head et al (1976), this also allovred
comparisons between the two chromatographic methods.
(2) DOCA-sal t model .
Porton derived male rats (70-100g) were unilatera'lly nephrectomised
on the left side under pentobarbital anaesthesia (somg.rg-1) and, after a
one week recovery period, injected subcutaneousìy tvrice weekl,v rvith DQCA
1
(20mg.Kg-') and allowed normal salíne to drink ad libitum. Litter mates
were sham operated,'injected in the same manner lv'ith the vehicle
(benzyl alcohol: peanut o'ii, 1:20) and allowed tap water to drink. The
group receiving DOCA-alone v¡ere injected with the same regimen as above,
without having a kidney removed or saline to drink. Indirect blood pressure
estimations were taken using a tail cuff coupled with a sphygmomanometer,
and a doppler flow probe coup'ìed with a DC amolifier and headphone set.
This procedure was similar to that descríbed by Reìchle (IglI). Measurernents
were taken once or twice weekly prior to and during the treatment period.
Rats were familiarised with the restraint cages prior to the comniencement
of indirect blood pressure determinations.
(3) Endogenous Catecholamine assay"
The endogenous NA, adrenaline (A) and dopamine (oA) contents cfperchoric acid (0.15M) extracts of tissues were determined by the perchlorjc
radioenzymatic assay of Da Prada and Zürcher (1976), as modÍfied by Crabb
et al (1980). The method is described in detail in the General Methods
(Chapter 2). The procedure followed was that tissues were rapidly removed
138.
2.91!0'18
t
1-70r0.21
10
DffiMffi
UNTREATE0 (n=5¡
COCAINE (n=51
00CA ln=51
COC . DQCA (n'9r p<0'05
tT.=Eo
(v)
IIoEc
0.5
0
Fig. 8.1
a
NA OOMA DOPE6 NMN OMDA
This shows the uptake and metabolism of 7-C labelled(-)3H.n¡n (O.18uM) in the rat tail artery in n¡nol.g-1.3Omin-1.
Also shown are the effects of cocaine (29uM), DOCA (27v14), andcocaine plus DOCA or, 3H.NA uptake and metabotite formation.* indicates significance (p=O.05); unpaired t-test.
Ëtiii
139.
from the rats and held at 4oC. Tissues were blotted and weighed before the
catechol ami nes were extracted 'i n 0. 15M HCI 0O at 4oC . The pri nci pa'l of
this assay invoìves the O-methylation of the catecholamines by CCMT with ,
3H.S-ud.nosyìmethionine providing the 3H-lub.lìed methyì group in a
favourable incubat'ing environment. The remainder of the assay involves
a series of solvent and aqueous extractions, and a purification step,
before the three 3H.O-methylated products are seÞarated by thìn ìayer
chrornatography (flC¡, and the tritium content of the regions corresponding
to unl abel I ed carrì ers determi ned by 1 iqu'id sc'inti I I ation spectrometry.
The levels of the catecholamines of the unknown samp'les are then determined
by comparison with their respective standard curves constructed by assayìng,
in paral'lel, samples with known amounts of the three catecholamjnes. The
assay was verified by the recovery,'in parallel samples, of known amounts
of commercial'ly aquired 3H.metabolites (3H.no.*.tanephrinu,3H.metanephrine
an,l 3H.methoxytyramine) . Resul ts were then expressecl as arithmet'ic means
(1 tfre standard error of the mean) in nmol .g-1 wet weight. The sensitiv'ity
of the assay was greater than required to detect the endogenous catecholamìne
contents of tissues; jn fact the acid extracts were normally diluted
(1:5 or 1:10) to coincide their levels with the most linear part of the
standard curves ( i .e. I ess than 12pmo'l .ml -1) .
RESULTS
(1) l'{ormotensive tissues.
(a) Noradrenaline. As shovrn in F'ig. 8.1, the metabolism of (-)3H.run
(0.1.8uM) in the rat tail artery was characterised by a 15-fold accumulation
of unchanged 3H.NA and the format'ion of 3u.nOpEe as the major metabolite
(40%), followed uy 3rr.oMDA (34%),3H.DOMA (19%) and 3H.NMN (6%). 0f rhe
3H.l'lR removed from the tissue, approxìmate'ly two thirds accumulated
unchanged and one third metabolised. The ratio of individual metaboljtes
t 40.
Table 8.l-
A comparison of two chromatographic techniques for separating catecholaminemetabolites
(a) tait artery incubated with (-)Stt.¡¡A (O.SO Ulvt) (incubating medium only)
Method n DOMA DOPEG NMN VMA MOPEG
(U) raif artery incubated with (1)5H.rso (o.er u¡{).
Method n
Válues shown are means + SEM in nmoL.g-l.SO min-1.
Tissue3H. rso
MediumSH.tut"otso
Tissue3H. r¡"otso
TLC
COLUMN 3
3
r,52 lO .25
r_.50 to.l_s
0.l-8 tO. Og
0. t_5 t0. 08
0.55 t0.o8 o.87 tO.06
0.64 19.31 0.O9 tO.OO
COLU¡{N
TLC
10
l_0
1.86 10.17
1.85 tO.1s
4./,9 lO.35 0.59 l0 . 02
3.90 +1.22 o.72 10.o8
141.
appearing in the incubating medium to those retained by the tÍssue was
lowest in the case of 3H.oopEe (I7%) and highest in the case of 3H.t¡Ni,l
(60%). A similar pattern of 3H.NA uptake and 3H.metauolite formation
lvas apparent when the incubating medium was assayed by'both column and
thìn layer chromatographjc methods (Table 8.1). This comparison also
indicated that 3H.VMA rvas the major component of the 3U.Ol,toR fraction.
Inhibition of neuronal uptake by cocaine (29uM) (Fig. 8.1) was
associated wÌth, (i) a decrease in both the accumulation of 3H.NA and
the formation of 3tt.oOp¡e (each by aporoximateìy 70%), (ii) no s'ignifìcant
effect on the 3H.ONDR o.3ll.DOMA formation, and (iii) a three-fold increase
in 3H.NMN formation. In the absence of cocainerìnhíbÍtion of extraneuronal
uptake by DOCA (27vM), (i) significantìy decreased the accumulation of3H.tlA by 40%, (ii ) did not affect 3H.NMN formation, and ('iii ) signifìcantì-v
increased the formation of 3H.oOprg by 40%. In the presence of cocaine,
DOCA sign'ificantly decreased the accelerated rate of 3H.ttl¡t¡l formation and
3H.OUOR formation when compared wjth arteries treated with cocaine aìone,
to a level similar to that seen in the untreated vessels. Sjmilarly, ìn
the presence of DOCA, cocaine significantly decreased the accelerated
rate of 3H.nOpEe-format.ion seen in the preparatìon lreated r¿ith DOCA a1one,
to a level similar to that in the preparation treated wjth cocaine alone.
The fonnation of 3H.OOUn was not sìgnificant'ly influenced by either cocaine
and/or DOCA, however, treatment with DOCA alone tended to increar. 3H.DOI,|A
formation. The formation of 3H.ONOR lvas only significantly decreased by
DOCA in the cocaine treateci preparatjon.
These results poìnt to a ìargely neuronal origin of the processes
involved in 3H.NA accumulation and 3H.DOPEG format'ion ìn the untreated
rat tail artery.
142.
a
30 39t0'2 r03
1.0
0'5
tlo
TAIL ARTERY
a
NA OOMA OOPEG
ATRIUM
N A DOI',IA DOPEG
C0NTROL (n=51
D OCA-solt (n =5 )
* p<0'05
OMDA
C0NTR0L (n=6)
DOCA-solt (n= 6l
OMDA
nt
I
.=E
CÞrIcrl
oE
0
+62
n
0.
0 l*rÉrNMN
Fig. 8.2 The uptake and metabolism of_ 215,6-C labetled (-)3H.tr¡t(o.fg pl'l) in nmoÌ.g-1 .5Omin-1 in normotensive and DoCA-saIt
hlrpertensive rat taiL arteries and left atria. This shows simiLarpatterns of metabolite formations in the two tissues, despite theIower uptake of unchanged 3H.ma by the atria.* indicates significance (p-0.05); unpaired t-test.
5-0
ì 43.
CONTR0L I n=12 I
00CA 127 yltl I ln=5 I
* .p<0.05
L.O
a
MeO.lS0
ARTERY
m
uØ
3.0
2-0
1.0
0
1'cEoal
T?oÊÊ
t
IS0TAI L
IS0 MeOJSO
ATRIUM
Fig. 8.3
and left atrium.* indicates significance (p<0.05); unpairecl t-test.
The effect of DOCA (22 vU) on the accumulation andmetabolism of (t)SH.ISO (0.81 uM) in rat tait artery
ì 44.
0'75
?:--tUNTREATED (n5)
COCAINE (29¡¡M I (n=5)
* p<0'05t
Tc.EoS o.zsIoEc
0.50
IS0 Me0IS0
Fis. 8.1 The effect of cocaine (29 uM) on the accumulation andmetabolism of (!)3n¡so (o.ra uÞl) in nmol.g-1. Somin-l
in the isolated rat tail artery.* indicates sigrnificance (p <o.05) ; unpaired t-test.
0
TabIe
The effect of DOCA (ZZ VW) on the accumulation and metabol-isnt of (I)SH.ISO in tissues from normotensive andDOCl\-sal,t hypertensive rats.Val-ues shown are means + SEM.* indicates significance (p<0.05) compared with controls; unpaired t-test.
8.2
Tissue Trea'bment n
BP
(mm Hg)
ISO
( uM)
Tissue3H. rso
NiI DOCA
Totar 3tt.l¡"otsonmol. g-1.3omin-1.
NiT DOCA
è(tl
.53
. t_1
2.O2 + O
0.65 t 0
0.66 t 0.09
1 .01- t 0. 25
6035
35
.05oq
+0+0
1.91 t 0.51
2.52 ! O.Sg
. l_1
.13to+0
1 .01o,72
0.32 t 0.05
0.19 t o.o4
0.75 t 0.150.92 t 0.11
o.2L ! O.O2
o.19 t 0.02
0.81_
o .81lt
+zt6
l_01
1,49
1011314916
66
7
7
Control-DOCA-salt( S-weex)
Control
DOCA-salt( 3-weex )
TAIL ARTERY
ATRIUM
146.
In the isolated left atrium, the accumulat'ion of unchanged 3H.ruA
was about half that seen in the tail artery (as indicated in norntotensive
control tissues'in Fig. 8.2), but the pattern of 3H.metabolites was
simjlar both qua'litatively and quantitativeìy to that seen in the tail
artery at the same substrate concentration. ihe source of 3H.metabolites
was not examined in the atrium in view of the extensive evidence in the
rat heart that the deaminated catechol metabolites (DOPEG and D0l'14) are
neuronal in orjgin and the 0-methyiated metabol'ite (NMN) is extraneuronal
in origìn (Fiebig and Trendelenburg 1978b).
(b) Isoprenal ine.
In contrast to (-)3H.NA, there was only a small accumulation of)
(*)3tt.IS0 by the rat tail artery; the major metabolite was 3H.pt.0lsO
tfig. 8.3 and Table 8.2). A minor proportion of 3H appeared in the 'OMDA'
fraction when assayed by the column chromatographìc method, but the
"metabol'ite(s)" responsible was not identified as it was not apparent in
tissues analysed by the thin layer chromatographic method. As shown in
Table 8.1, the results obtained by the two methods were quantìtatively
similar and both indjcated 3H.NuOlSO as the major metaboiite. 0f the
3H.tSO removed by the tissue, approximate'ly 80îá was meiabolised. The
amount of 3H.IS0 metaboljsed was aporoximateìy ha'lf that of 3H.NA at
the same substrate concentration. The largely extraneuronal origìn cf3H.M.0IS0 was indicated by a 60% reduction in its rate of formation in ihe
presence of DOCA (27utl) (Fig. 8.3 and Table 8.2). However, DOCA was
without a significant effect on either the sìight accunulation ot 3H.IS0,
or on the formation of the "metabolite(s)" appearing in the 'OMDA' fractícn
Cocaine (29uM) caused a small signif icant decrease (bv 25%) in both 3tl.tSO
accumulation and 3H.MeOlS0 formation in the tail artery (Fig. 8.4),
suggest'ing a m'inor pronortion of 3H.IS0 accumulated and was O-methJ¡lated
in neuronal structures.
147 .
æ0 T_O CONTROL
- -tr DOCA-SALT......4 DOCA ALONE
r P<0.05t
//
{
1
T IME
,ü- - -þ'
t
;J-
E
sLrjfrÞtn.nLr,frfLooC)
00
180
160
140
120
t
1000 '2
f weeks I
3 L 5
Fig. 8.7 The effect chronic DOCA-salt treatment on the bLoodpressure (measured indirectly), compared with sham-
operated rats, injected with the vehicle alone, and rats injectedvlith the same dose of DOCA alone. The nu¡nber of observations at eachpoint varies. For the DOCA-salt rats n=lg, 19r 54r T5r 9 and 9 foreach point; for the control rats n=11, 50, 5g, 91, 14 and 9; and forthe DOCA alone rats n=6 at each point.* indicates significance (p<O.05); unpaired t-test.
ì 48.
50
M
CONTROL (n=12!
CHRONIC DOCA (nl2)lr'O
30
r'.=Cå 2'0c'l
IcD
Ê 10c
0I S0 MeOISO
TAIL ARTERY
I S0 MeOISO
ATRIUM
Fis. 8.6 The effect of chronic DOCA (20mg.Kg-1 i.t¡*cted sub-cutaneousl-y twice weekly) on the accumulation of unchanged
(t)3u.ISO and the fo¡.mation of 3H.t"teotso in nmol.g-1.30min-1 in theisolated rat tail arter-y and left atrium incubated with (1)3H.fSO(o.ar pu).
t49.
28
26
10
5
-tr--o
ISO
Me0IS0
¡
I
-'-7I/l
FI
.EEocî
TC'l
oEc
,ç'
00 2 3 L 13
ISO. CONC lnmot. ml-f I
The accumulation of unchanged (t)3n.tSO and the formationof SH.l¡eOrSO in nmol-.g-1.sO*irr-l i., the isolated rat tail
Fis. 8. s
artery with substrate concentrations ranging from 0.18 to 12.8 ¡rM (n=6).This shows that saturation of these pathways had not occurred at thesubstrate concentrations routinely used in the present studyi ie,0.18 and O.81 UM.
150.Table 8.5 The accumulation and metabolism of (-)5H.ive in normotensive and DoCA-salt hypertensive rat tait arteries. Metabolite'aLues in brackets refer to effh:x into the incub¿rting medium. only. Val-ues are means +SEM. * indicates signj-ficance(p<0.05)
nBP
(mm Hg)NA ¡TM
( 3u. ta¡et )
TissueNA DOMA
Metabolite Formation nrnolDOPEG
-'l _'1S -. 30min '
NMNTreatment
Control-
DOCA-saltt J-week )
OMDA
(o.og r o.r-o)
o.73 10.07)
o.34
o.4L
+ 0.03
+ o.03
33
42 t o.03
0
o
+ 0.01_
(r.67(2.re
t 0.18 )
! o.].7)
73
99*
1 0.05
n
0
t o.o7
O.42 + O.05
08 t 0.01
06 + 0.01
0
0
0.05
o.60
10.00t 0.01
(0.0s r o.01)
(0.04 r o.ot_)
(o.rs r o.04)(o.ro t o.03)
o.L2
0. L0
+ 0.01
! o.02
0.08 + O.O2
0. s9
o.56
! o.02
+ 0.03
0.6s
0.90
+ o.Q4
t 0.08
(2.+o r 0.17)
(2.7s t 0.17)
(1.6e
(2.0610.14)t 0.14)
0.61
o.46
t 0.04
+ 0.05
O.50 + O.02
! o.02
+ o.o2
0.18
c.2L
+ o.o2+ 0.05
o.31
O . /./t
(1.08 !o.26)
(r-.06 t o.18)
(o.s2 t o.os)(o.or t o.os)
t 0.01+ o.0l_
0.1_6
o.1.4
O.21 ! O.O2
1
1
82 t 0.06
82 t 0.05
5
J
02 ! o.zL
88 + O.29
t o.22
! o.25
3.15
2.92
2.AL + 1 .81
o.12(7-c)
0.18(z,s,o-c)
0 .59(2,5,6-c)
0.59(z,a-c¡
0.18(z ,e-c)
0.18
+Ê
t1116
L79
135 !4+'7t-93
fc
1,42 + 3
206 16
+z
!5
720
t73
L20 +.)
+q200
9
7
5
5
9
9
t2
t2
9
7
5
Ccntrol
DOCA-saIt( 3-week )
Control
DOCA-salt( 3-week )
Cont:'ol
DOCA-sal-t( 3-week )
ControÌ
DOCA-sal-t( 6-week )
Untreated
151.
In a separate experiment, the kinet'ics of 3H.ISO accumulatjon and
3H.N.0tS0 format'ion were examined over a concentration range of 0.18 to
12.8pM As shown in Fig.8.5, ne'ither the rate of 3H.ISO accumulat'ion
no. 3H.Me0IS0 formation weré approaching saturation at the concentratjons
of 3H.IS0 more routinely used in the present study (0.18 and 0.81uM).
The amounts of unchanged 3tl.ISO retained by the tìssue and the
formation of 3H.M.OIS0 were considerabìy loler in the isolated left atrium
than in the tail artery (Tabl e 8.2 and Fig. 8.3). The content of 3H.lSO
per gram of tissue was only 40-70% of the 3tl.IS0 content per m1 cf the
bathing mediurn which, in vÍew of the S-second wæh, suggests that it was
largely conf:ined to the extracellular compartment. The extraneuronal
onigin of the 3H.M.0IS0 *u, indicated by the 'inhibitory effect of DOCA,
which lvas comparable with that of the tail artery (faUle 8.2 and Fig. 8.3).
Chronic treatment with DOCA alone for five weeks had no effect on
either the accumulation of 3H.IS0 (0.81uM) or the formation of 3H.t,t.olSO
in the tail artery or atrium (Tab'le 8.5 and Fig. 8.6). Thjs DOCA treatmeni
was not associated with changes in blood pressure (Fjg. 8.7).
(2) Hypertens Íve ti ssues .
The rise in blood pressure assocjated with the D0CA-salt treatment
is shown in Fig. 8.7. After three weeks of treatment their mean systolìc
blood pressure was 160nrnHg, compared with 117 mmHg in control rats (means
of approximately 75 animals), although the magn'itude of this increase did
fluctuate with different treatment series (as seen in Table 8.3).
In initial experiments the accumulation and metabolism of (-)3U(Z-C)
NA (0.12uM) was compared in tail arteries from a Eroup of three week
D0CA-salt hypertensive rats and their normotensive controls (fanle S.3).
152.
I
3.0 39c0'2 c0'3
10
CONTROL I n=5 I
HYPERTENSIVE (n=51
* p<0'05
tcÉo(Ð
TqoEc
t05
NA DOMÁ DOPEG NMN OMDA
Fio. 8.8 The uptake of unchanged SH.ue and the formation of theJH. metabolites in nmol.g-1.SOmin-l in isolated tailarteries from control and DocA-saLt rats treated for 3 weeks,incubated with 2,5,6-C labelled SH.¡¡t (O.fe utt).* indicates significance (p<0.05); unpaired t-test.
I
0
3+
2.
t 53.
CONTROL (n=91
HYPERTENT¡YE ¡¡=71(6 WEEKI ¿p<0O5
IcEo
c1.
IIoEc
1.5
10
0.5
0
nt
t
NA DOMA DOPEG NMN OMDA
Fis.8.9
arteries from control and DOCA-salt rats treated for 6 weeks,incubated with 2,5,6-C labelled (-)sn.¡¡l (O.fe uM). The dashedline indicates the amount which effh¡xed into the bathing medium,compared with that retained by the tissue.* indicates significance (p<0.05); unpaired t-test.
The uptake of unchanged stt.*O and, the formation ofSH.metaboLites in nmol.g-r.3Omin-1 in isolated tail
I
I
I
I
I
,
154.
The comparison was repeated in a separate experjment at a higher substrate
concentrat'ion (0.Sgul't), but it was subsequently 'learned that the (-)3H.run
used (from a dìfferent commercial source) was partially labelled on the
B-C atom (Starke et al, 1980; confirmed in personal communicatìon with
NEN). For this reason, the above comparisons were repeated in two further
experiments using (-)3H.NA labelled on the 2,5 and 6-C atoms on the
aromatic ring to avoid doubts about the location of the 3H on the 7-C
or 8-C atom. These latter comparìsons, involv'ing a total af 23 normotensive
and 21 hypertensive rats failed to reveal any consistent differences in
either the accumulation of unchanged amine or the format'ion of3H.metabolites. A possible exceptìon ìs, at the low substrate concentrat'ion,
the mean values of 3H.DOMA and 3H.OMDA formation were increased (bv
approximately 30%) in the hypertensive vessels, a'lthough these increases
were only significant in the case of the comparison using the 2,5,6-C
labelle¿ 3H.ltlR. In the latter comparison (shourn Ín Fig.8.8, and Table
8.3), the accumulation of unchanged 3H.NA was also significantìy increased
by 30%. There were no s'ignifÍcant differences in the rates of 3H.DOPEG
ot^3H.NMN formation in either comparison.
0n1y one comparison v\ras carried out on six-week DOCA-salt treated
rats (Tab'le 8.3 and also Fig. 8.9). The on'ly signÍf icant changes were
a 38% increase in 3H.OMDA and a 34% decrease iu 3H.DOPEG format'ion.
Holvever, these changes were small, and since 7,8-C labelled 3H.NA was
used in these experiments, it is poss'ible that the h'igher rates of 3H.OMDA
f ormation (compared wi th the 2,5 ,6-C 3H
. ¡tR) ref I ected varyi ng amounts of
tritiated water in this fraction (as explaìned previously).
The accumulation and metabolism of 2,5,6-C labelled (-)3H.NA (0.18uM)
in isolated left aùria were compared in one group of three-week hypertensive
rats and their normotensive controls. These results (Fig.B.2 and Table 8.4i
r 55.
Tab1e A.4The accumuLation a¡rd metabolism of (-)Values shown are means t SEM.* indicates significance (p<0.05); unpaired t-test.
3g.Ne in normotensive and DOCA-saIt hypertensive rat left atria.
TreatmentBP
(rnm HS)NA uM
( 3tt. t"¡"t )
TissueNAn DOMA
MetaboLite Formation
DOPEG
nmol.g-1. gomin-l
NMI{ OMDA
0.51 t 0.05
0.30 1 0.03
o.o3 + o.o1
0.03 t 0.00
o.75 + O.Lz
o .76 I 0.09
0.39 t 0.o7
0.39 Ì 0.03
L.67 ! O.24
1. r-9 t 0.16
o.18(2 15 r6-C)
L35+1
L93+7
6
6DOCA-sa1t
Control
156
Table 8.5
The accumulation and metabol-ism of (t)3H.fSO in tissues from normotensive and DOCA-salt hypertensive rats.Values shown are means + SEM.* indicates significance (pcO.05); unpaired t-test.
Tissue Treatment nBP
(rnm ug¡ISO(ulr)
TissueISO
Total- 3H.l'¡"orsonmor . g. -1 . 3omin-l
4.25 + O.06
3.70 ! O.41
5.25 + O .64
5.48 t 0.65
0.65 0.o4
1.66 t O.27
r./"8 ! o.20
1.86 t 0.L8
L.90 + O.27
1.36 t 0.O9
1_.61 t 0.19
2./*7 + O.30
2.59 ! O.28
0.1-8 0.o2
o.32 + O.O2
0.33 t 0.05
0.63 + 0.10
0.51 + 0,10
0 .81_
t1
0 .81
0.1_8
il
o.81
lt
0.Br_
19119
119t2
l_18 t 1
1r812
TLg!2
191_ + 9Jc
11811
IL3+2
18
20
!2
1-2
5
18
20
I2
L2
Control
DOCA-salt( S-week)Control
DOCÀ-alone( 5-week )
Untreated
Control-
DOCA-saIt( S-week)
Control
DOCA-alone( S-week )
TAIL ARTERY
ATRIUM
,c'-E
o(YI
TIc,E
5.0
4.0
3.0
2'O
1.0
nn
,/IS0 MeO.ISO
ATRIUM
ì 57.
CONTROL I n=12 I
HYPERTENSIVE ln=20 I
0ISO Me0.ISO
TAIL ARTERY
Fig. L10
isolated tail arteries and left atria from control and DOCA-saltrats treated for 5 weeks, incubated with (t)3H.ISo (o.81 uM).
The accumulation of unchanged 5H.fSO and the formationof the 3H.metabolite, 3H.Mãorso, in nmor.g-1.3omin-l in
159 .
did not reveal any s'ignificant changes in the accumulation of unchanged
amine or the rates of 3H.metabolite formation in the hypertensive rat
atri a .
The accumulation and metaboljsm of 3H.IS0 (0.BluM) in the tail
artery and left atrium (Table 8.5 and F'ig. B.i0) revealed no significant
differences between the tissues from normotensive and D0CA-salt
hypertensi ve rats.
(3) Endogenous Catecholamine contents.
The contents of NA, adrenaline and dopamine in tail arteries,
hearts and atria are summarised in Table 8.6. In nornlotensive rats, the
tail arterids had high levels of NA but negligible contents of adrena'line
(A) and dopamine (DA). The comparison between two separate groups (A and
B), representing prox'imal segments in A and distal segments jn B, when
assayed, suggested that the NA content diminished ci'istal ly.
There were no significant differences between the endogenous
catecholamine contents of three-week normotensive and hypertensive vessels,
nor was there any evidence of hypertrophy in the latter tail arterjes.
After six weeks of treatment the hypertensive vessels showed evidence of
hypertrophy and had sign'ificant'ly higher NA and adrenaline contents"
In normotensive rats, the contents of NA, adrenaline and dopamine
in tlie whole heart were approximately one tenth those of the tail artery.
The contents of the left atria were approximately four-fold greater than
those of the whole heart. The hearts of the hypertensive rats were
significant'ly hypertrophied at three and ab six-weeks; the hypertrophy
at three weeks was associated with significant decreases jn the NA,
adrenaline and dopamine contents. The ccnrparison between a small number
of atria suggested that changes in the atrial contents reflected those
in the whole heart.
160.
D ISCUSS I ON
(1) Origin of metabolites ìn normotensive tissues.
(a) Tail artery. The pattern of accumulation and metabolism of
NA in the tail artery is cons'istent with evidence. based on histochemical
observat'ions (Hodge and Robinson, I972) and pharrnacoìogical evjdence
(l{yse, Ig73), confirmed by the endogenous NA contents (tfris study),
that the rat tail artery has a dense sympathetjc innervatjon. Thus the
effects of cocaine indicated that the removal of NA by thjs tissue was
largely via uptake into sympathetìc nerves and its subsequent deaminaticn
represents an important pathway of metabolism. The extraneuronal
inactivation appears to be -quantitat'ively jmportant since the net removal
and metabolism of NA by the tissue jn the presence of cocaine was about
half that in the absence of cocaine. However, the contribution of the
corticosteroid-sensitive extraneuronal pathway in inactivat'ing NA appears
to be quantìtatively less signifìcant. since, a'lthough D0CA s'ignificantly
reduced NA accumulation by 40%, it was without effect on NMN formation
when neuronal uptake was unimpaired. Extraneuronal inactivation appeared
to be of greater importance when neuronal uptake was blocked. Hence itnray be concluded that, in the rat taj'l artery, the extraneuronal uptake
system is quantìtat'iveìy iess important than the neuronal system in the
inactivation of NA. The effects of cocaine, and of DOCA, indicated that
3H.ogpEe was largely neuronal in orjgin, and at least 67% of the 3H.Nt',tttl
was formed extraneuronal'ly'in a corticosteroid-sensitive O-methylating
compartment. Although jn the cocaine-treated vessel, 3H.OMDA formation
was signifìcantly decreased by DOCA, this decrease was small (30%). lJence
the origin(s) of the major proportìon of the OMDA fraction, and also the
small amount of DOMA forrned, cannot be ìdentified with either neuronal or'
corticosteroìd-sensitive extraneuronal compartments. Insensitivity of
QMDA formation to corticosteroids has been reported in other tjssues.
16i.
As already discussed'in Chapter 4, it has been proposed that DOPEG which
effluxes from the ne!"ves nray diffuse directìy into effector cells anci
undergo O-methylation in the rat heart (fieUig and Trendelenburg,lgT8b).
A similar conclusion was arrìved at by Henseìing et a'l (1978b jn rabb'it
aortic strips. Schrold and Nedergaard (1981) showed that OMDA coul.J be
formed in the isolated adventitia of the rabbit aorta, possibìy by
fibroblasts which have been reported in the adventitia of this tissue
by Levin (I974) and contain both the enzynres COMT and MAO (Jacobow'itz, 1972).
Conceivably access of NA into these cells is not affected by stero'ids.
In view of the seemingly m'inor role p'layed by the extraneul onal
0-methyiat'ing system in the inact'ivation of NA, the capac'ity cf the tail
artery to O-methylate IS0 'is surprisingly h'igh. The rate of fornration
of MeOISO was 56% of that seen in the rabbit ear artery lvhich is regarded
as having a well developed extraneuronal uptake system (Flead et al,1980)"
Furthermore, the tail artery O-methyìated IS0 at a rate which was
approximately one-half the total rate of metabolism of NA and 2.7 fald
greater than the rate of O-meth-vlation of NA in the cocaine treateC vessels
where, presumably, only the extraneuronal 0-methylat'ing pathlay was
available. These observat'ions suggest that the steroid-sensjtive
extraneuronal inactivating system of the rat taiì artery is not poorly
developed, but rather that it has a lolv affjnity for NA compared with that
for JSO. However, the possibility must also be considered that not al'ì
of the IS0 was metabolised in a steroid-sensitive 0-methylating compartment,
The small but significant inhibiiory effect of cocaine sLrggesled that 25%
of the MeOIS0 may have been derived from e neuronal'compartment. 0n
the other hand, 'it is alsc probable that the 60% reduction of ItleOIS()
formation by DOCA is an underestimate of the steroid-sensitive extranr:urtrnal
contribution, sìnce,from studies in the rat heart (Iversen and Salt, i97C)
t62.
and the rabbit ear artery (Johnson and de la Lande,1978),'it seems
l i kel-v that the stero'id i s a competì ti ve j nhi b'itor of extraneuronal
O-methyl ati on .
(b) Atrium. Although the origins of the metabo'lites of NA in the atria
were not investigated, the fact that the ratio of the relative accumulat'ions
of unchanged amine in the atria and tail artery (O.SZ) was similar to the
ratio of their endogenous contents (0.35) suggests that the major
proportion of the amine accumulated in the atria was ìn sympathetic
nerves. Nevertheless, with the possible exception of 3H.NMN, the rates
of metabol'ite formation in the atria were strikingly similar to those
in the ta'i'l ,artery. This finding suggests that, in the atria, proportionai 1,,
more of the amine wh'ich is removed by neuronal uptake is deaminated than
Ís the case in the tail artery. The formation of 3H.NMN uuu, less
than 'in the tail artery and represented only ?% of the total rnetabol'ite
formati on.
The accumulatjon of IS0 and its rate of O-methylation was also
markedly less in the atrium than in the tajl artery. This result was
surprising in view of the capacity of the whole rat heart to accumulate
and metabolise IS0 (Bönisch and Trendelenburg,IgT4b). The values in the
atria also differ frorn those in ventricular slices reported by Bönisch
et al (L974) in that, jn the atria, the accumulatÍon of IS0 was markedly
less while the rate of MeOISO förmation was approximateiy fcur-fold
greater. It is conce'ivable that the lower values in the atria and
ventricular slices reflect more l'imited diffusion of the substra+"e'into
the latter tissues (th'ickness approx'imately 0.5mm) compared with the
tail artery (wall thickness approxima.tely 0.O7rnnr). As in the case of
the ta'i1 artery, DOCA decreased but djd not abojish MeOIS0 format'ion
(by 60%). In view of evìdence in whole heart (Bönisch et a1,1974),'it
is probable that thjs fjnding again reflects the competit'ive nature of t.he
action of D0CA.
163.
(2) DOCA-sal t treatment.
The most reproduc'ible of the changes in metabolism of NA in the
hypertensive tail artery was the increase in 0MDA formation at low
substrate concentrations. This increase, although only 30%, was
significant in one of the two groups of three-week hypertensjve vessels.
The interpretation of this effect is comp'licated by a number of factors,
(a) the '0MDA' fraction is the least 'pure'of the metabolite fractions
obtained by the cascade column chromatograph'ic nlethod, and (b) in the
case of 7,3-C labelled amine (as used in the six-week hypertensive
vesseìs) the '0MDA' fraction would have also included trit'iated water
derived fron'r the action of MAO on the g-C 3U molecules. As already
discussed, the origin of the OMDA fractÍon in this tissue is unknown Ín
view of the relatÍve failure of both cocaine and DOCA to significant'ly
modify its formation. However, the present results do suggest that the
apparent increase in OMDA formation is not due to an increase'in the
steroid-sensitive O-methylating oathway of the vessel, since the
increases in OMDA formation were not associated with increases in the
formation of NMN, or in the formation of MeOISO frorn IS0. Simj'lar'ly,'it
seems unìike1y that jncreases in OMDA were assocjated with increased
neuronal deaminating activity, since the major product of neuronal
dearnination (DOPEG) was enhanced 'in onìy one of the three-week
companisons, and then not significant'ly so. Further, the increase jn
OMDA formation in the six-week hypertensive vessels were associated with
a significant decrease in DOPEG formation. Hence, the present study
can offer little support for the association of NA inactivation in
the tail artery and the hypertension induced by DOCA-salt treatment.
Hence these metabolic data provide no firm evjdence that the increase
in sensitivity of the hypertensive tail artery to NA (reported by Venning
and de la Lande,1981) resulted from an alteration in the neuronal
164.
inactivation pathway. In this respect the results support the
conclusions of these workers derived from the failure of cocaine to
influence this increased sensitivity.
The failure to observe differences in accumulation and neuronal
deamination of NA in atria of hyoertens'ive rats'is more puzzling in
view of the hypertrophy and reduced endogenous NA content associated with
the hypertension. A possible explanation is that the hyoertrophy is
accompanied by para'llel increases'in the activity of the neuronal
deaminating and extraneuronal O-methylating enzymes.
In genera'l , the absence of changes in the rates of 0-methy'latìon
of NA, or IS0, in both the tail artery and the atria argues strongly
against the possibiljty that the activity of the extraneuronal O-methylating
pathway is modified during DOCA-salt treatment. These results differ from
those of de Champ'lain (1967) lvho observed a significant reduction in the
retention of NMN'in isolated whole hearts of DOCA-saìt hypertensive rats
perfused with (*)3H.tlR. However, as jndìcated above, d'ifferences
between isolaied cardiac tissues and the whole perfused heart may reflect
more adequate perfusion and diffusjvity of substrate and metabolites in
the latter preparation.
Finally, it should be noted that the data suggests thaÙ chronic
treatment with corticosteroid is without effect on the actirrity of the
steroid-sensitìve extraneuronal uptake system. This conclusion is basec!
on the failure of chronic DOCA treatment to influence the O-methylatìon
of IS0, both when the treatment is associated with an increase in bloocj
pressure (after DOCA-salt) and when it is without effect on blood
pressure (after DOCA alone). The effect of chronic DOCA treatment on
NA metabolism uras not examined.
CHAPTER 9
GENERAL DISCUSSION
16 5.
CHAPTER 9
GENERAL DISCUSSION
( 1) Resumd of b'i ochemi cal data .
(a) Rabb'it ear artery.
The studies'in Chapters 3 and 4 established that the surface of
entry of NA into the artery wa'|l exerted a major influence on jts
metabolic fate. Entry vìa the adventitial surface waò assocìated with
a predominantly neuronal deamination inactivating pathway, while entry
via the intima was associated wi th predom'inantly extraneuronal O-methylat'ion.
The differeríce was explained'in terms of the interactjon between a
number of factors of which the main ones were:
(i) the location of the sympathetic nerves at the medial-adventit'ial
border, together with evidence that the nerves are the principle
site of formation of the deaminated metabolites;
(ii) the uniform distribution of the majorìty of the O-methyìation
sites throughout the media;
(iil¡ the probability of a high d'iffusiv'ity of NA and its metabolites'in
the advent'itia compared with the media; and
(iv) the presence of a declining concentration of NA from its surface of
entry into the vessel wall and the opposite surface.
The D0PEG formation ratio (i.e., the ratio of the total amounts of
D0PEG effluxing from the vessel when ìncubated with EXT NA, and
with INT NA) was used as an index of the concentrations achr'eved by
EXT and by INT NA in the region of the nerve termjnals. Hence, this
ratio served as an approximate measure of the magnitude of the decline
in concentratÍon of INT NA between the intima and the nerve terminals.
166.
Qualitatively, the difference in metabol'ism of EXT and INT NA
appeared to be independent of r¡rall th'ickness and perfusion pressure (i.e.,
the changes accompanying constriction), the presence or absence of Caì+,
the presence or absence of o1 receptor blockade, or the rate of ìntraluminal
flow. However, quantitat'ively the patterns of NA metabol'ism, particularl-v
that of INT NA, was altered by these factors. Thus the DOPEG formation
ratio was greatest (24) in the Ca++ media, 10 in Ca++ free media, 4.4 inff,
Ca" free media with prazosin, and lowest (2.7) when the flow rate was
2.0 ml.min-l. The effect of constriction on the efflux of NMN from
both surfaces differed from that of DOPEG 'in thai effi ux of NltlN tended
to decrease wittr increasìng constriction during incubation with EXT NA,
as well as during incubation with INT NA.
These results suggested that the constrictor tone of the vessel was
capable of modifying, in a substantial way, the metabolism of INT NA
and the 0-methylation of EXT NA, a'lthough havìng little influence on the
format'ion of deaminated metaboiites from EXT NA. Factors which may have
been respons'it¡le for these djfferences were considered in the Discussjon
of Chapter 4. These include<l: (a) to explain the effects of constrict'ion;
changes in the thickness of the media compared with the adventitia,
foldirrg of the lumen and changes'in the diffusÍv'ity of NA, and (b) to
exp'lain the effects of flow rate; the h'igher flow rate leading to an
increase in basal perfusion pressure, an expanded lumen and a decrease
in wall thickness. For the most part, these possìble explanations tvere
specu'lative since data wh'ich would enable i,he'ir critical assessment was
unavailable. However, there is evidence from other studies in ihis
laboratory relating to the possjble roles of changes in perfusion
pressure and of diffus'iv'ity during constrictìorr. De la lande et al (1980)
167 .
Table 9.L The efflwith (-)
formation of metabol(o.30 FM) (Levin; 1974).
Tissue Preparation DOMA DOPEG NMN
ux of metabolites from rabbit ear arteries incubated3H.ue (O.ra ul¡) (present study), compared with theites in the rabbit aorta incubated with (-)su.Wa
Metabolism nmol .g'-1 .3omin-1 .
OMDA
ear artery INT 3H.NA
INT E EXT3H.ne
NAEXT ="
o.L2+o.o2
(5%)
o.72+0 .08(32%)
2.46+o.22(65%)
3.05+o.L7(5o%)
o.95+o. 06(12%)
0 .5810.04
(s%)
1 .30+o,08(2r%)
o.47+0.05(2r%)
0.55+o.o7(ß%)
1 .16+0.03(Le%)
o.61+0. 07(L4%)
' o.51lo.L2
(s%)
aorta isolatedmedia
isolatedadventitia
intactaorta
o. 03+0. 01
(2%)
o.26+0.03(L6%)
o.L410.02
(e%)
0.1_9lo.o2(L/.%)
o.13to.1l_
(8%)
r.23to.1L(76%)
0.58+0.05(43%)
1,.L7+0.09(74%)
0.13+0.03
(8%)
o.5110.05(1o%)
o. l_1+Q.O2
(7%)
o .04+0 .00
(3%)
168.
found that in arteries perfused at a constant rate, the diffusjon
coefficient of EXT l4C.sorbitol decreased sìgnifìcantly duríng constric'ujon,
i..e., when both wal I thickness and perfus'ion pressure increased. However,
the decrease in diffusiv'ity djd not occur in vessels perfused at a constant
pressure, i.e., when only the wall thickness decreased. Theìr results
imp'ly that an'increase in intraluminal perfus'ion pnessure alone can
decrease the diffusiv'ity of a substance diffusìng from the adventit'ia
to the intima. Such an effect could be explained ìn terms of an increased
bulk flow of solution across the wall from the intima to the adventitia
which would oppose the diffusion of NA resulting from its concentratjon
gradient. Th'e problem with this expìanatjon is that, if correct, the
flux of INT NA across the wall should be greater in the constricted
than in the relaxed vessel. The present data indicates that the opposìte,
in fact, occurs. Further experiments designed to measure the diffusion
coefficient of INT 14C.rerb'itol at various levels of constrjction, and
perfus'ion pressure, may help to resolve these apparent paradoxes.
The different metaboljsms of INT and of EXT NA complement the
earljer findings of Levin (1974) on the relative metabolisms in the
isolated adventitìa and iso'ìated media of the rabbit aorta. The
relative proportions of metabolites are compared in lable 9.1. Itshoul d be noted that the val ues shown for rabbi t ear artery segments
represents the total efflux into the bathing media of vessels incubatedI
with (-)'H.NA (0.18uM), whereas values from rabbit aorta represents total
metabolite format'ion (i.e., efflux into the bathing medìum pìus the
tissue extract) in vessels jncubated wjth (-)3H.NA (0.30pM). However, jn
the case of DOPEG and NMN, the difference is small since these have high
medium to tissue ratios (shown'in Fig.3.3, Chapter 3). Further
169.
(as discusseci later) the rate of metabol'ism of NA in the perfused segment
of ear artery appears to be greater than that in the'isolated artery strip.
Nevertheless, the data ìndicates that in both tissues the prìmary site
of deamjnation of NA (i.e., DOPEG and DOMA format'ion) js associated
with the adventjtia and specìfjcally with the sympathetic nerves ,
and Q-methylation (i.e., NMN formation) primarily associated with
the media. In the case of the aorta, further confirmation of the
sites of these pathways is reported jn a recent study otl the effects
of surface of entry on NA metabolism by Hensel'ing (1980b1). His abstract
does not repot't the method used to restrict the entry of NA to one
surface only.'
The origin of the OMDA fraction (i .e., MOPEG'and VI'IA) appear to
be more complex than those of the renrain'ing metabol'ites" In- the present
study eviclence was presented that a significant proport'ion of M0PEG ìs
formed by the O-meihylation of DOPEG. Evidence of such a mechanism u/as
not possible in Levin's study on the isolated adventitja and media of
the aorta s'ince th'is mechanism reljes on DOPEG formed'in the advent'itia,
being Q-methylated probabìy in the media. The quantitative contribution
of the D0PEG O-methyìation mechanjsm of MOPEG forrnation may, however, be
less important in the aorta since'its media is approxìmately 3-fold thicker
than the media of the ear artery. This is because the present ev'idence
indicates that DOPEG O-ntethy'lat'ion is more important in smooth nuscle
cells close to the sympathetic nerves than in more distant cells. A
second Q-methylat'ion pathlvay of OMDA formatjon was resìstant to hydrocortiscne
and appeared to account. ent'ire1y for the formation of this fraction when
NA entered via the intjma. Since this pa'uhlay predominated in the reg'ions
more Cistant from the nerve terminals, it may weì1 play a more important
170.
role in the thicker walled aorta. Hovrever, it might also be argued
that, as a resul t of reserp'ine pretreatment of the rabb'it, the
quantitative contribution of the O-methylatìon of DOPEG to lv|OPEG
format'ion in the rabbìt ear artery was overestimated iri present study.
Thìs is because reserpine pretrea.tment greatly jncreased D0PEG formation
(shown in Chapter 3, Fig. 3.1).
The poss'ible origin of VMA was not inyestigated. Its formation is
un1 i kely to i nvol ve the same cocaj ne-sensi ti ve corti costeroi d-
insensitjve mechanism responsible for the Q-methyìation of DOPEG,
sjnce this mechanjsm reljes on the h'igh lipophilicjty of DOPEG as the
factor whÍch'enables the glycoì to diffuse into the extraneuronal
O-methy'lating compartment (Mack and Bönjsch, 1979). These workers
also showed that the l'ipid soìubility of DOMA js poor compared wìth
that of D0PEG; hence the same mechan'ism ìs unlikeìy to account for
VMA formatìon. An extension of the present study to include sepai'ation
of the OMDA fraction into VMA and M0PEG rvill be required before the siteis)
of formation of these nletabolites can be further analysed.
No attempt has been made to'identìfy sulphate conjugates in the
present study. Sulphate conjugates are well known in brain and liver
homogenates (i4eek and Neff , I973). Fut ther, during 'in v'ivo stud'ies,
most l{A and metabolites are found in urine as conjugates (Goodall and
Al ton, 1968) . It seems l'ike1y, there'tore, that such conjugation occurs
by a secondary mechanism at a site distant. from the blood vessel wall,
ê.9., the liver (Meek and Neff , 1973) . The possib'il'ity that the 0MDA
fractjon could include sulphate conjugates seems unf ikel.y, since Head
et al (1980) could jdentify only O-methyìated metabolites when rabbit
ear arteries lvere incubated with 3U.lS0 and the incubate analysed by TLC.
L7t.
A similar conclusion was drawn by Levi n (ßlq) in studjes with the rabb.it
aorta. He was unable to detect any metabolites of NA (other than the 5
considered 'in the present study) using paper chromatography, with the
possible except'ion of a smal'l peak containing 0.15% of the total radio-
activity applied to the p'late (Rf = 0.9) on chromatograms obtained from
isolated advent'itia, but not from isolated medja. This peak did not
coincide with any of the unlabelled metabolites (not conjugated).
In summary, the present metabolic stud'ies have further defjned
the pathways of NA metabolism and orig'in of metabolites'in the rabbjt
ear artery. An inter-relatjon between metabolism and constriction has
been revealed. For its further understanding, there is a requinement
for further experìments to expand this relationship to include more
precise correl ation of mcrphol ogì cal and metabo'l'ic changes .
(b) Metabol'ism in artery strips and segments.
Comparison of the results on isolated artery strips, and other
perfused segments incubated with INT plus EXT 3H.run, suggested that
there was sign'ifìcantly less metabol'ite formation'in the artery strip.
Aìthough the strips were taken from the immediate'ly distal regìon of
the artery from which the segment was derived, 'it cannot be argued that
regiona'l differences in metabol ism are respons'ib1e, since, in certain
experiments where proximal strips were used (Chapter 3, Table 3.i), the
metabolism of NA jn these strips did not differ significantly from
that of more djstal strips measured in other experiments (Chapter 3,
Table 3.4) .
The loler rate of metabol'ism of NA jn strips is d'ifficult to expìaìn,
since the effect of cr-rtting an artery segment to form a s'urip was íound
to have l'ittle effect on metabolite efflux in the non-perfused preparations
t72.
(Chapter 3, Table 3.1). The possibi'lity that the artery strip was
constricted is excluded, since many of the studies using strips were
carried out in Ca++-free media with prazosin present. The possibility
that entry of substrate into the strip may have been lìmited by
inadequate stirring seems unììke'ly since the contìnuous bubblìng
(with 95% 02,5% C}Z) ensured that the strip was constantly agitated
in the incubating medium. Furthernrore, these incubation condjtjons
correspond exactly w'ith those to which the adventi+.'ia was subjected'in
the perfused segment.
There rema'ins the possibility that the pulsat'ions cf the wall of
the perfused segment, imposed by the effect of the roller pump on the
intraluminal flow, may have caused a type of'stirring'of the solutes
in the extracellular compartment, thus enabling the substrate to
penetrate more freely to the inactivation sites and promote more rap'id
efflux of metabol'ites from these s'ites. Th'is question could t¡e resolved
by further experiments in whjch a non-pulsating punrp vJas employed.
These results do, however, reise an'important aspect of technique which
has been'largeìy ignored in most studies of in liltq metabolism in
blood vessels. It is suggested that such studies should be carrjed
out under cond'itions more closely related to the physiologìcaì situat'ion,
i.e., segmerrts should be used and these should be perfused'intraluminaì1y
if quantitative extrapo'lations of the'in vjtro data to the in vivo
situatjon are to be meaningful.
(c) Rat taiì artery.
A'lthough somewhat tangential to ihe ma'in t.heme of this study, the
study on the metabol ism of NA, and IS0, in the rat ta'ii artery showed
that, again, DOPEG was the nrajor" metabol'ite and lvas neuronal in origin,
whereas as NMN and MeOIS0 were extraneuronal in or'jgin, and steroid
sensitjve. The main difference between this preparation and the rabbìt
17_?.
ear artery appears to be in the resistance of OMDA fornlation to cocaine.
This may concejvably be due to the fact that the ta'il arteries were not
derived from reserpine pretreated rats, so that the absolute rate of
DOPEG format'ion was considerably less than in the reserp'in'ised rabb'it
ear arteries, i.e., the contribution of the DOPEG O-methylation
mechanism would be less. However, another factor to be taken.into
account is that the major component of the OMDA fraction, present ìn
incubates of this vessel, was VMA and not M0PEG, unfike the rabbit
ear artery.
The fa'ilure to detect cons'istent changes in the metabol'ism of NA,
or IS0, in tail arteries of the DOCA-sa'lt hypertensive rats does not
necessanily imply that such changes do not occur. In view of the
observation that, in the rabbit ear artery, the metabolism of NA in
perfused segments exceeded that in artery strips,'it is quite possible
that the use of non-perfused segments in the rat studies meant that the
conditions vrere not opt'irnaì for detect'ing such changes. Extens jons
of th'is study to include perfused segrnents would appear to be desirab'le,
(2) Pharmacol og'ical Impl 'i cati ons .
(a) Perfused segments
As outlined in the General Introduction [Chapter 1) the
influence of the surface of entry on the steady-state vasoconstrictor
response to NA, comprising a 10-20 tjrnes greater sensitìvìty to INT NA
than to EXT NA, has been related primarily to the'location of the
sympathetic nerve terminals at the medìal-advent'itial border. The
lesser effect of EXT NA was exp'lained'in terms of its removal by the
nerves as it diffused from the adventitia to the media, leading to a
lower concentration at the receptors ìn the media.
I74.
The results of the present studies provide biochemìcal ev'idence
i n support of the mod'if i ed model ( sfuwn i n Fi g. I.2) . Thus the neuronal
inactivatìon of NA, as indicated by the for"nration of DOPEG and DOMA,
was quantitat'iveìy much greater when NA entered v'ia the adventitia. Th'is
finding provides a further indication that the orig'ina'l model proposed
by de la Lande et al (1967) (shown in Fig. 1.1), where the concentration
of INT NA was assumed to be uniform throughout the wall, Was an over-
simp'lification. It supports the concept that the rninor role of neuronal
uptake in the response to INT NA is due, ìn part at least, to the
relative failure of INT NA to penetrate to the region of the nerve
termi nal s .
The effect of cocaine on the'inact'ivation of NA is, qualitatively
at least, in agreement with the pharmacological data. The pharmacoiogìcai
experiments showed that, 'in the presence of cocai ne, the sensì t'ivi ty to
EXT NA was greatly enhanced and approacheci that to INT NA (de la Lande
and Waterson, 1967). Simi I ar'ly, the present resul ts shor^/eci that cocaine ,
by its potent inhib'itory effect on DOPEG and DOMA efflux, e1íminated the
differences between the metabolisms of INT and of EXT NA. There are,
however, some quantitative discrepancies. The magnitude of the decrease
in concentratjon of EXT NA resulting from neuronal uptake, as deduced
from pharmacolog'icai studies, was i0-20 folcl (de la Lande et al,1967).
However, in the present study, the total increase in flux of EXT NA p'ìus
the increase efflux of NMN into the INT perfusate, produced by cocaine,
was only 2.5 fold. This difference may be part'ly due to the different
experimental conditions used in the present study, where the INT NA
was recirculated continuously through the lumen for the 30 minute perioC
L75.
of incubation. In the pharmacoìog'ical studies, the intraluminal perfusate
was not rec'irculated. De la Lande and Graefe (included in de la Lancie
et al., 1980) observed that in three of four arteries perfused at the
same rate as in the present study (O.S ml.mjn-l¡, brt in lvhich the
intraluminal penfusate was not recirculated, cocaine produced increases
in flux of EXT NA of the order of six fold. These workers used a Ca++-
free medjum, but may not have prevented constriction comp'ìete1y' as an
o-receptor blocking agent was not present. However, ìn view of the
present evjdence of Chapter 4, that when the artery constricts, i.e.,
increases its wall thickness, the flux of amjne across the wall is
decreased, the presence of an o-receptor antagonist in the present
experìments cannot explain the relatively small effect of cocaine on
the flux of EXT NA. This js because coca'ine normal'ly enhances the
constrictor response to NA; in the experiments of de la Lande and
Graefe, such an effect of cocajne vlould tend to reduce the flux of
EXT NA across the vessel wall, below that occurrjng when the artery
is relaxed.
A third factor to be taken into account is that, in the present
experiments, the vessels were derived from reserpinised rabbits. More
amine may be removed by neurona'l uptake in normal arteries where the
amine, after its uptake, is bound in neuronal vesicles. However, in
some as yet unpublished pharmacological experiments, de la Lancle and
Jonsson (1981) found that, in six reserpinised veSseìs, cocaine
potentiated the sensitivity to EXT NA by approxìmately 25 fold; i.e.,
to about the same extent as in normal arteries perfused at the same rate.1
These experiments were carrjed out at a flow rate of 2.0 ml.min
medi um.
'in Ca++
176.
Fina'lly, it should be noted that the discrepancies between the
effects of neuronal uptake on removal of EXT NA, as deduced from
pharmacoìogical and biochemical experiments, will occur if part of
cocaine's effect on sensitiv'ity to NA is due to an extraneuronal act'ion.
The metabo'l'ic experiments prov'ided no evidence of such an actjon jn that
NMN formation from INT NA was not affected by coca'ine. From its
pharmaco'logìcal actions, it can be argued that if an extraneuronal
action of cocaine is present, it is'of minorimportance. Th'is is
because the increase in sensitivity to INT NA produced by cocajne was
on'ly 1.5 fold (de la Lande,1975). However, even the argument that
this small in'crease is primari'ìy extraneuronal is weakened by evidence,
indicated prevìousìy'in Chapter 1, that cocaine does not potentìate the
response of the rabbit ear artery to anotheF cxl-rêcêptor agon'ist,
namely methoxami ne .
(b) Role of flow rate
The influence of flow rate was examined only at a late stage cf
the study. It was not examined earlier jn view of evidence that the
diffusion coefficient of 14C. sorb'itol when applied to the adventitia,,,ras
unaffected by increasìng the flow rate from 0.25 ml.min-1 to 1.0 ml.mjn-l
(de la Lande et al, 1980). Furthermore, the meta.bolic data (Chapter 4)
indicated that, in the absence of neuronal uptake, there was ljttledifference between the metabol'isms of INT and EXT NA; i.e., be+-ween the
metabolism of NA when added to a well-st'irred solution bathing the
adventitia, and its metabolism when perfusing the lumen. However, the
resul ts of some recent pharmaco'logìca'l experiments (de ìa Lande and
Jonsson, unpublished) do suggest that flow rate did influence the
vasoconstrjctor response to INT NA. it was found that, in resero'ine
r77 .
pre-treated vessels, the vasoconstnictor activ'ity to INT NA, although
not that to EXT NA, was less when the vessels were perfused at C.5 ml.min-1
than at 2.0 ml.min-1. This phenomenon, still under investìgation, prompted
the extension of the present study to include vessels perfused at 2.0 ml.min
As shou¡n in Chapter 4, the metabolism of INT NA, although not that of
EXT NA,.was increased by approx'imately 40% at the hìgher flow rate.
Together with the pharmacologìcal results, this f ind'ing imp'lies that
at the higher flow rate, INT NA penetrates more readily'into the vessel
wall. However, even jf this is the case, the biochemical data derìved
from the vessels perfused at 0.5 ml .min-1 upp.urc of pharrnaco'logical
significance.' This is because the reserp'inised Ca++-free vessels,
perf used at 0.5 ml .mi n-1, sti I I di spl ayed a marked di f ference betrn¡een
their sensitivity to INT and EXT NA (Table 4.3, Chapter 4).-
(c) The magni tude of the grad'ient of concentrat'ion.
As indicated in the General Introductìon (Chapter 1), the
pharmacological and h'istochemical evidence suggested that, when NA was
applied to one surface onìy, there was at least a l0-fold decline in
concentration of NA across the vessel wall. The index of this ratio
'in the present study, i .e. , the DOPEG formation rat'io, 'in vessel s
perfused at 0.5 ml .min-l, ranged from 4.4 in the relax.ed vessel to 24
in constricted vessels. The h'igher value is probab'ly more relevant to
the pharmacological and histochemìcal studies since the latter studies
were carried out on constricted vessels. This was inherent in the nature
of the pharmacologìcal studies, where estimates of sensitivìty are based
on ratios of INT and EXT NA which are equipotent in producing constriction.
In the case of histochemical studies of de la Lande et al (1970), the
vessels (reserpinised) were exposed to h'igh concentrations of NA (3rM);
t79.
43% of the total metabolite efflux. That NMN was formed in a steroid
sensitive extraneuronal compartment was evident by its virtual el'imination
by hydrocortisone. When the biochemical data is related to the
pharmacolog'ical data, the results impìy thatraìthough uptake and
O-methylation of NA into this compartment is the major pathway of
inactivation of INT NA, thìs process has on'ly a rninor effect on the
concentration of NA at its receptors in the smooth muscle. The difference
may.reflect the reported low affinity of NA for the extraneuronal uptake
process (lversen, 1967). In support, isoprenaìine was taken up and
O-methy'lated at approximateìy three tirnes the rate of NA (shown ìn
Table 6.2) . 'The difference between the rates of O-methy'latìon of NA
and IS0 accords well with the findings of de la Lande and Johnson that
DOCA potentjated the dilator (ß2-receptor mediated) response to IS0 on
the vessel by a factor of 2.5.
As discussed 'in Chapter 4, the O-methylation pathway ìnvolved
in the format'ion of the OMDA fraction',^ras'insensitive to hydrocortisone.
Hence, the effect of this inactívating pathway on the concentration of
NA at its receptors will not be tested by the actjon of DOCA on the
pharmacologìca1 response to NA. Nevertheless, an ind'irect guìde to the
pharmaco'logicaì importance of the OMDA pathway would be provided by
the relative pharmacological data on the effects of COMT inhibjtion and
steroid-sensitjve extraneuronal uptake ính'ibjtion. Inspect'ion of the
results of Johnson (1975) shows that U0521 potentiated the response to
INT and EXT NA by factors of 1.6 and 2.2 respectively (compared with 1.i
and 1.2for DOCA under the same conditions). It wor¡ld appear from these
resuìts, that the steroid-insensitive O-methylation system plays a role
at least as great as that of the steroid-sens'it'ive system in cclntrolììng
the level of NA at its receptors. Unfortunateìy the further pharmacoìogicaì
180.
evaluation of the importance of the OMDA pathway is limited by the absence
of a specific inhibitor. The present study indicated that phenoxybenzarnìne
is an inhfbitor, but its a-receptor.blocking act'ion and its lack of
specificity precludes its use'in such a pharmacological evaluation.
By a different approach to that of Kalsner(L972a), the studjes
in Chapter 7 confirmed that the concentration of NA at its receptors
was sìgnificantly increased when, in the absence of neuronal and sterojd-
sensitive extraneuronal uptake, INT NA distribution in the wall became
more uniform because it was unable to escape from the adventitial surface
when the EXT bath'ing medium was replaced with oil. The greater effect
of EXT NA, than oil, on the response to INT NA, is compatible with
the presence of an ìnactivating mechanism which is neither cocaine or
steroi d sens i ti ve. Th'is coul d conce'ivably correspond to the OMDA formati on
whi ch was 'insensi ii ve to these agents .
APPENDIX 1
THE DIFFUSION OF A SUBSTANCE
THROUGH A SLAB, WITH INTERNAL
GINERATION OF A METABOLITE
tBt.
ç,oot-Co()CorJ
oot-ëo-o2V,
cx
geneîèf ion k x
elinination4#
0.5 1.0
locotion in slob
FiS. A .1 The distribution of a substance in steady diffusionthrough a slab of thickness X. The concentration at
location x represents a balance between the rate of generationfrom the substrate and the rate of elimination by diffusion.
0
182.
APPENDIX 1
The djffusion of a substance through a slab,
with internal generation of a metaboljte.
A substrate with a concentratiorr c is app'ìied to the face x = X
of a slab of material while the face x = 0 is maintained at a concentrat'ion
of zero. Under conditions of simple, steady diffusjon through the slab,
the profile of concentratjon is linear. The concentratjon of the substanie
at any posit'ion w'ithin the slab is proportional to the ci'istance x from
the face at zero concentration is sholn in Fig. A.1 and is s'imp1y
' n-xVX
If a metabolite is formed continuously by reaction of the substraie
within the slab, it must pass from the s'lab by diffus'ion and must deve'lop
a profìle of concentration to do so. The shape of the profile js
determined by the condjtion that the rate of generat'ion of metabolite
at a part'icular locality and its rate of diffusion from that locality
must reach equiIibrium.
The rate of generation of the metabolite is presumed to be proportjonal
to the local concentration of the substance which is, in turn, proportional
to position, x, in the slab. The rate of diffusion js dictated by Fick's
Law of Díffusion. The necessary equilibrjum is
n=-ff Q)
where k is the rate constant for generation, D is the dÍffusivity of the
metabolite and c is its local concentration.
(1)
I 82a.
0 0.5 1.0
Xlocqtion in slob
Fiq. A .2 The distribution of metabolite in the slab. The maximumvalue is at location x/X = O.577. The concentration
gradient and flr"rx from face x=X is twice that from face x=0.
oCoC)
o=o.ctooE
x
183.
Integrating equation (2) from x = 0 to x = X gives
+=-o(å;-rfiror (3)
in which (Íi)O is the concentration gradient at the face x = 0.
InteErati ng aga'in yi el ds
dca
XJ (4)c = x(ax 6
for the distribution of metaboljte through the slab.
Invoking the condjtions that the concentration of metabol'ite is
zero at each of the faces, X = 0 and x = X, gives values for the gradient
at each face of
'dc(ä)o
, ,dCand (äi)x
and the fonnula
(7)
for the distribution of concentration.
The profile of concentration is illustrated in Fig.4.2 and shows a
maximutn value ut f = 0.577. The fluxes of metabolite from the two faces
of the s,]ab may be found by appìyìng the formula
Q = -Då;
kD0
kx2D6 (5)
(6)_ kx2- - D3
)Xr¡/
Xrkx3"D6
(B)
to the respective values of the concentration gradìent in (4) and (5)
above. The fJuxes u.. -$ at the face x = 0, and S.a the face x = X.
The flux of metabolite from the face at wh'ich the substrate enters
is exactly twice as great as the flux from the other face.
To apply this result to diffusion through the media of an artery,
some account of the presence of the adventitia at one of the surfaces
must be taken. The effect of such adventitia must be to impede djfl'usion
from that partìcular surface. The balance of flows of metabolite would be
shifted in favour of the opposite surface.
APPENDIX 2
DRUGS AND CHEMICALS
I84.
APPENDIX 2
Drugs and Chemicals
(1) Krebs bicarbonate solution. The following ana'lytic grade chemicals were
used to prepare this physio'logical bathing medium.
NaCl
KCI
NaHC
120mM
4mM
25mM
1mM
6mM
0.01mM
2mM
0. smM
9mM
og
K2HP04
Gl ucose
EDTA
CaCl2
MgC1,
ascorbic acid **
*
.,r In many experiments CaCl2 was omitted from the bathing medium.
** Ascorbic acid was normalìy added to warmed, gassed Krebs solution
2-3 minutes before the preparation of the 3H.catecho'lamine incubating
so'luti on.
(2) Cocaine HCI (McFarlane Smith Ltd.) rvas dissolved in normal saline
(154mM) giving a stock concentration of 2.9mM such that 0.01m1
per m'l of bathing medium yielded a final concentration of 29vM.
185 .
(3) Hydrocorti sone sod'ium succi nate ( "So1 u-Cortef" , Upjohn Co. , Kal amazoo)
was dissolved 'in aqueous solution contaÍning nhosphate buffers (sodìun
phosphate,3.8mM, and anhydrous sodium diphosphate,3TmM) and benzyl
alcohol (46mM) giving a stock concentration of hydrocort'isone of
103mM; 0.004m1 of this solution per mì of bathing medìum y'ielded
a qoncentration of 413uM hydrocortisone.
(4) Phenoxybenzamine HCI (Smith, Kline and French Laboratories) was
dissolved in normal saline (154nrM) giv'ing a stock concentration of
3.3mI'1; 0.01m.l of thjs solution per m1 of bathing medium.y'ielded a
concentratjon of 33uM.
(5) U0521 (3,4-dihydroxy-2-methy'l propiophenone) (The Upjohn Co., Kalanazooi
was di ssol ved i n normal sal i ne (tS+mt'l) contai ni ng ascorbi c aci d
(0.6mM), giving a stock solution of 5.5mM; 0.0lm1 of th'is solut'ion
per m'l of bathing med'ium y'ielded a concentration of 55pM.
(6) Deoxycorticosterone acetate (4-pregnen-21-ol-3,20-dione, Koch-Light
Laboratorîes Ltd., Coinbrook Bucks, England) was dissolved in ethanol
(analytica'l grade) givîng a stock solution of 5.4rnM; 0.005m,l of ih'is
solution per ml of Krebs solution yielded a concentration af 27vþ1.
(7) Reserp'ine (Serpasil, Ciba) was dissolved with phosphoric acid,
ascorbic ac'id, 'Versene Fe3', 'in propy'lene g'lycol and sterile water
for injection. Each ampoule (1ml ) contained 4.1mM reserpine.
(S) Alumina (lvterck-AG) was prepared by the method of Crout (1961). The
Principa'l of this method involves gently boiling 200-3009 in 1.0 l'itre
of 2M HCI for 30 minutes. When cool the acid was decanted and the
alumina washed I?. to 15 tjmes with distilled water, al'lowing 5 mìnutes
between washes. The pH was adjusted to 4-5 before drying the alumina
in an evaporation dish for 2-3 hours in an oven at 1000C.
t86.
(9) DOI^JEX-50l^l (Sjgma Chemical Company) hydrogen form (4% cross linked
and dry mesh 200-400) was purified as described by Graefe et al (1973).
The principal of this method jnvolves repeated washing of 200-3009
of the resjn w'ith 2M NaOH (containing 1% EDTA) at 500C until the
supernatant is clear; the iesin is then washed 3-4 times with
(i) distilled water, and (ii) with 6M l-iCl:ethanol (1:1), and then
equilibrated to pH = 2 with 0.01M HCl.
(10) (-)noradrenaline bjtartrate (l-arterenol bjtartrate, Sigma Chem'icai
Company) was dissolved in normal saline (154mM) conta'ining ascorbic
acid (0.6mM), giv'ing a stock solution of 0.6M (as the base).
Dilutjons were made as required.
(11) (1)Isoprenaline HCI (dl-isoproterenol HC'1, Sígma Chemical Company)
was prepared as in (10).
(LZ) Paraffin oil (F.H.Faulding and Co. Ltd., Adelaide) was warmed to
37oC and bubbled with 95% 02, 5% C}Z prior to use.
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